Monosaccharide Sugars: Chemical Synthesis by Chain Elongation, Degradation, and Epimerization

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MONOSACCHARIDE SUGARS

Chemical Synthesis by Chain Elongation, Degradation, and Epimerization

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MONOSACCHARIDE SUGARS Chemical Synthesis by Chain Elongation, Degradation, and Epimerization

Zolt~n Gy6rgyde~k Department of Organic Chemistry Lajos Kossuth University Debrecen, Hungary

Istv~n F. Pelyv~s Research Group of Antibiotics of the Hungarian Academy of Sciences Lajos Kossuth University Debrecen, Hungary

ACADEMIC PRESS San Diego London Boston New York

Sydney Tokyo Toronto

This b o o k is printed on acid-free paper. ( ~

Copyright 9 1998 by ACADEMIC PRESS All Rights Reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without permission in writing from the publisher. Academic Press a division of Harcourt Brace & Company 525 B Street, Suite 1900, San Diego, California 92101-4495, USA http://w w w. apnet, com Academic Press Limited 24-28 Oval Road, London NW1 7DX, UK http://w w w. hbuk. co. uk/ap/ Library of Congress Cataloging-in-Publication Data Gy6rgyde4k, Zolt4n. Monosaccharide sugars : chemical synthesis by chain elongation, degradation, and epimerization / by Zolt4n Gy6rgyde4k, Istv4n F. Pelyv4s. p. cm. Includes bibliographical references (p. - ) and index. ISBN 0-12-550360-1 (alk. paper) 1. Monosaccharides--Synthesis. I. Pelyv4s, I. F. (Istv4n F.), date. II. Title. QD321.G97 1997 547' .781304595--dc21 97-23437 CIP

PRINTED IN THE UNITED STATES OF AMERICA 97 98 99 00 01 02 Q W 9 8 7 6

5

4

3

2

1

Dedicated to our Master, the late Professor Rezs6 Bognfir, on the occasion of his 85th birth anniversary


CONTENTS

FOREWORD xiii PREFACE xv ABBREVIATIONS AND ACRONYMS Introduction

I Ascending

xvii

I

Synthesis

of Monosaccharides

3

1.1. Buildup with Total Synthesis 3 1.1.1. The Formose Reaction 3 1.1.2. Synthesis from Glyceraldehyde 15 References to Sections 1.1.1 and 1.1.2 17 1.2. Buildup of Sugars with Ascending Synthesis 18 1.2.1. The Cyanohydrin Synthesis (Kiliani-Fischer Synthesis) 18 References to Section 1.2.1 28 1.2.2. Synthesis of Acid Derivatives by Means of Nucleophilic Substitution 30 References to Section 1.2.2 40

oo

VII

viii

CO-'-NTE"N TS

.

.

.

.

.

.

.

.

.

.

.

.

.

1.2.3. Nitroalkane Syntheses 40 1.2.3.1. Chain Extension with Nitromethane 42 1.2.3.2. Chain Extension with Nitroethane 50 1.2.3.3. Chain Extension with Nitroethanol 52 1.2.3.4. Chain Extension with Nitroalkane Carboxylic Acids 53 1.2.3.5. Nitroaldol Condensation of Monosaccharides Containing Nitromethyl Groups 56 1.2.3.6. Nitroaldol Condensations with 1-Deoxy-l-Nitroaldoses 64 1.2.3.7. Nitroaldol Condensation with C-GlycopyranosylNitromethane Derivatives 67 References to Section 1.2.3 69 1.2.4. Chain Extension with Diazoalkanes 72 1.2.4.1. Hydrolysis of Diazoketones 72 1.2.4.2. Addition of Diazomethane to aldehydo-Sugars 75 References to Section 1.2.4 8 0 1.2.5. Chain Extension with Malonester Derivatives 81 1.2.5.1. Condensation of Open-Chain Monosaccharides with Active Methylene Compounds (KnoevenagelDoebner Reaction) 82 1.2.5.2. Chain Extension with Malonate Derivatives 90 References to Section 1.2.5 99 1.2.6. Chain Extension with Phosphoranes: Olefination Reactions for Synthesis of Chain-Extended Monosaccharides 100 1.2.6.1. Chain Extension with Nonstabilized Ylides 101 1.2.6.2. Extension of the Saccharide Chain with ( Oxoalkylidene) Phosphoranes 128 1.2.6.3. Elongation of the Sugar Chain with Alkoxycarbonylmethylenephosphoranes 140 1.2.6.4. Chain Extension of Saccharides with Phosphoryl-Stabilized Carbanions 159 References to Section 1.2.6 177 1.2.7. Miscellaneous Methods for Extension of the Monosaccharide Chain 188 1.2.7.1. Chain Extension by Addition of Organometallic Compounds to an Aldehyde or Lactol Function of Saccharides 188

CONTENTS

IX

1.2.7.1'1. Extension of the Sugar Chain by the Addition of Grignard Reagents to aldehydo-Sugars 188 1.2.7.1.2. Extension of the Sugar Chain by Addition of Lithioorganic Compounds to aldehydo-Sugar Derivatives 199 1.2.7.1.3. Chain Extension of Saccharides with Organosilicon, Organotin and Organo-boron Compounds 215 1.2.7.2. Chain Extension of aldehydo-Sugars with Thiazole, Furan, and Pyrrole Derivatives 234 1.2.7.3. The Reformatsky Reaction for the Chain Extension of Saccharides 245 1.2.7. 4. Preparation of Sugar Derivatives by Means of Chain Extension Based on AldolCondensation 252 1.2.7.5. Chain Extension of Unsaturated Sugars to Nonbranched Derivatives 274 1.2.7.5.1. Chain Extension of Glycals and Hydroxyglycals with Alkenes 274 1.2.7.5.2. Chain Extension by Hydroformylation of Glycals (Oxo Reaction) 277 1.2. 7.5.3. Ascending Syntheses by Claisen Rearrangement of Glycals 283 1.2.7.6. Ascending Synthesis with aldehydoSaccharides 286 1.2.7. 7. Chain Extension of Aldonic Acids and Aldonolactones 297 1.2.7.8. Anhydroaldononitriles: The C-1 ChainExtended Products of Cyclic Aldose Derivatives 316 1.2. 7.9. Chain Extension of Saccharides Starting with Acetylene Derivatives 331 1.2.7.10. Chain-extension of Halogenide Compounds 334 1.2.7.11. Ascending Syntheses with Sulfonic Acid Esters 347 1.2.7.12. Ascending Syntheses with NitrogenContaining Saccharides 352 References to Section 1.2.7 360

X

CONTENTS

2 Descending Syntheses of Monosaccharides

375

2.1. Disulfone Degradation 375 References to Section 2.1 389 2.2. Degradation of Calcium Salts of Aldonic Acids with Hydrogen Peroxide 389 References to Section 2.2 392 2.3. Descending Syntheses of Acylated Aldononitriles 393 References to Section 2.3 401 2.4. Degradation of Saccharides with Oxidative Methods 401 2.4.1. Degradation by Cleavage with Periodates 402 References to Section 2.4.1 417 2.4.2. Degradation by Means of Cleavage with Lead Tetraacetate 418 References to Section 2.4.2 424 2.4.3. Descending Syntheses of Onic Acid and Uronic Acid Derivatives 425 2.4.3.1. Descending Syntheses of Onic and Uronic Azides 425 2.4.3.2. Degradation of Onic and Uronic Amides with Hypochlorite 430 2.4.3.3. Descending Synthesis by Decarboxylation of Mercuric and Silver Salts of Uronic Acids 433 2.4.3.4. Decarboxylation of Uronic Acids with Lead Tetraacetate 436 2.4.3.5. Electrochemical Oxidation of Uronic Acids 441 2.4.3.6. Degradation of Ascorbic Acid Derivatives 442 References to Section 2.4.3 448 2.4.4. Oxidative Degradation of Aldoses to Aldonic Acids with Chain Shortening 450 References to Section 2.4.4 456 2.4.5. Degradation of Peroxide Derivatives of Saccharides 457 2.4.5.1. Descending Synthesis of Sugar-Derived 1-Phenylazohydroperoxides 457 2.4.5.2. Degradation of Saccharides by Fragmentation of Acylated Peroxyglycosides 458 References to Section 2.4.5 463 2.4.6. Chain Shortening of Saccharides by Means of Photochemical Methods 463

xi

CONTENTS

2.4.6.1. Light-Induced Degradation of Saccharides 463 2.4.6.2. Metal-Ion-Catalyzed Photochemical Descending Syntheses of Aldoses 466 References to Section 2.4.6 469

3 Preparation of Sugars with Isomerization

471

3.1. Epimerization of Saccharides in Alkaline Media 471 References to Section 3.1 477 3.2. Epimerization of Sugars with Molybdate Ions 478 References to Section 3.2 482 3.3. Epimerization of Saccharides with Amine Complexes of Transition and Alkaline Earth Metals 483 References to Section 3.3 491 Notes Added in Proof INDEX 499

493


FOREWORD

Carbohydrate chemistry has been an important part of organic chemistry for well over a century. In the hands of Emil Fischer it played a major role in the historical evolution of stereochemistry. Then came the protracted disagreement between Hudson and Haworth about the size of the sugar rings. Another important advance was the recognition of the importance of ascorbic acid and Reichstein's beautiful synthesis thereof. Many other natural products were recognized to be carbohydrates. Even polymers such as starch and cellulose are carbohydrates. Indeed, nature has the habit of attaching sugars to all kinds of molecules, even triterpenoids and steroids. The aminoglycoside antibiotics again played an important role in stimulating the further growth of carbohydrate chemistry. However, this is not the end of the story. Carbohydrates play an almost infinite role in the immune system and in cell recognition. Also, we cannot forget that DNA, RNA, and a host of modified nucleosides are all based on a carbohydrate component. Thus, carbohydrate chemistry will remain a major interest of organic chemists, biochemists, molecular biologists, and synthetic chemists for an indefinite period into the future. This book by Drs. Zoltfin Gy6rgydefik and Istvfin F. Pelyvfis is entitled

Monosaccharide Sugars: Synthesis by Chain Extension, Degradation, and ooo

XIII

xiv

FOREWORD

Epimerization. It provides the chemist with a very useful summary of the synthetic manipulation of monosaccharides, which are the simplest kind of carbohydrate. Nevertheless, you cannot build up complex carbohydrates, such as are needed in cell regulation, without beginning with something simpler and more readily available. This book presents a critical appreciation of synthetic methods for monosaccharides. It also deals with the use of monosaccharides for the production of "chirons" as defined by Stephen Hanessian. The synthesis of isotopically labeled carbohydrates is also covered. There are suitable experimental procedures included in each chapter. This book will be of benefit to anyone who has to deal with carbohydrate chemistry. It is concerned with the fundamental building blocks~the monosaccharides. In a world sinking under an avalanche of published journals, the struggle with the retrieval of important facts can be avoided by simply reading this book. Those who do will be grateful. D. H. R. Barton

PREFACE

The synthesis of new chiral organic compounds, and the improved synthesis of known substances, will always be a major task for the professional chemist. The stereoisomerism which can arise even when two appropriately substituted sp3-hybridized carbons are contained in a molecule makes it inevitable that the synthesis of such a molecule will call for the exercise of stereocontrol. For constructing a target molecule with multiple chirality centers, either total synthesis or assembly from smaller chiral blocks may be considered. The present book intends to help in recognizing such chiral units as have been employed, or can be used as readily available chiral starting materials for buildup of complex organic structures. Saccharides represent a unique family of polyfunctional compounds which can be chemically manipulated in a multitude of ways. This book presents, with the aid of illustrations and about 1700 references, previously applied and potentially useful strategies for the synthesis and degradation of monosaccharides. The result is a general overview and comparison of the construction of hardly available higher-carbon sugars, as well as smaller chiral synthons. When describing the individual methods in each chapter, unique supple-

XV

xvi

PREFACE

-

-

-

mentary collections of the prepared sugar derivatives are provided in the form of Tables, while representative, well-established experimental procedures illustrate the practical potential of the discussed synthetic transformation. We hope that these features will save tedious literature searching by the reader engaged in research and education on the chemistry and biochemistry of saccharides and many other natural products. We are indebted to our colleagues who helped us by making copies of some early papers available, and to Mr. Miklds Hornyfik for his invaluable technical assistance in editing the artwork of the book. We thank the Alexander von Humboldt Foundation (Bonn, Germany) and the Hungarian Science Foundation (Budapest, Hungary; Grants OTKA 19327 and 23138) for financial support in various stages of our research and in the preparation of this manuscript.

Zoltdn GyOrgydedk Istvdn F. Pelyvds

ABBREVIATIONS AND ACRONYMS

Ac AIBN All Ar Bn BOC Bu Bz chxn CpFe(CO) DAST DBU DCC DCHA DIPEA DMAP DMF DMSO DOPSA

acetyl 2,2'-azobisisobutyronitrile allyl aryl benzyl tert-butoxycarbonyl butyl benzoyl diisobutylcyclohexenediamine cyclopentadienyl-dicarbonyliron diethylaminosulfur trifluoride 1,5-diazabicyclo[5.4.0]undec-5-ene dicyclohexylcarbodiimide dicyclohexylamine diisopropyl ethylamine 4-dimethylaminopyridine N,N-dimethylformamide dimethyl sulfoxide [dimethyl(oxy)propyl] (dimethylsilyl)acetylene to

XVI!

eee

X V I JI

ABBREVIATIONS AND ACRONYMS

DQQ ee HMPA HPLC KDO LDA MCPBA MEM MOM Ms NMR Ph Phth Piv p.p.m. Py TBDMS TBDPS TBSOP tetmen Tf THF THP TLC TMS Tr

2,3-dichloro-5,6-dicyano-1,4-benzoquinone enantiomeric excess hexamethylphosphoric triamide high performance liquid chromatography 3-deoxy-D-manno-2-octulosonic acid lithium diisopropylamide 3-chloroperoxybenzoic acid 2-methoxy-ethoxymethyl methoxymethyl methanesulfonyl, mesyl nuclear magnetic resonance phenyl phthaloyl pivaloyl parts per million pyridine tert-b u tyl dim e t h ylsil yl tert-b utyl diphen ylsilyl 2-te rt-b u tyl dim e th ylsil yl o xyp yrr o l e N,N,N',N'-tetramethylene diamine

trifluoromethanesulfonyl tetrahydrofuran tetrahydropyranyl thin layer chromatography trimethylsilyl trityl (triphenylmethyl) Ts p-toluenesulfonyl (tosyl) Z carbobenzyloxy

INTRODUCTION

Knowledge of carbohydrate chemistry continues to move ahead on many fronts. The field has become a rather complex discipline, as shown by the huge number of publications cited Chemical Abstracts under the term "Carbohydrates," and by the new journals addressing the field in the last few years. Interest in the chemistry of carbohydrates has grown rapidly from the discovery of simple sugars in the nineteenth century to recognition of the biological roles of polyhydroxyalkyl aldehydes (aldoses) and polyhydroxyalkyl ketones (ketoses) in naturally occurring glycosides, nucleosides, oligoand polysaccharides, and certain antibiotics. Following the pioneering research on sugars (Tollens, Ledderhose, Dubrunfaut, etc.), the studies of Emil Fischer are considered milestones, which have since been successfully utilized by researchers to this day. The present book is aimed at treating carbohydrate chemistry through the eyes of a synthetic chemist who is using carbohydrates as naturally occurring, inexpensive starting materials in organic syntheses. A particularly attractive feature of carbohydrates is their chiral structure, permitting their use in synthetic research and in the chemical industry as "chiral pools." Numerous procedures have been known for the chain extension of ap-

2

INTRODUCTION

propriate sugars for synthesizing the target chiral compound (such as Nacetylneuraminic acid), or for the degradation of readily available sugars to chiral synthons with shorter carbon chains (such as D- or L-glyceraldehyde). This book presents and discusses the literature to date on methods for carbon-carbon bond formation and degradation in the field of sugars, offering the production of higher-carbon sugars and related compounds, or smaller chiral synthons, respectively, from simple carbohydrate derivatives. Procedures reported for the epimerization of sugars, which are of great practical importance for the stereochemical interconversion of carbohydrate derivatives, are also discussed. For the sake of simplicity, examples of these methodologies are taken from the field of nonbranched sugars exclusively, and discussion of neither the functional-group transformations involved and executed in the methods presented, nor the enzyme-mediated reactions, are within the scope of the book. Special emphasis was given to explaining and including results and experimental details from the early published literature, mostly in nonEnglish-speaking countries. Our intention was to generalize the experimental procedures, and to use the recently established International Union of Pure and Applied Chemistry (IUPAC) Nomenclature for Carbohydrates. However, in many cases, this new nomenclature may cause difficulties when searching for older (but still extremely useful and reliable) data in the literature. As mentioned above, the book is compiled into three major chapters; the first describes the reactions applicable to the chain extension of carbohydrates, the second summarizes the methods reported for chain shortening (degradation) of sugars, and the final chapter deals with the epimerization reactions of carbohydrate derivatives. To avoid the use of four-digit reference numbers, the references are placed at the end of each subchapter (section). For technical reasons the literature is covered to the beginning of 1996. However, important, more recent references are briefly discussed in the "Note Added in Proof" section.

ASCENDING SYNTHESIS OF MONOSACCHARIDES

I.I. BUILDUP

WITH

TOTAL

SYNTHESIS

I. I. I. T h e F o r m o s e Reaction

When the most simple aldehyde, formaldehyde, is treated with alkali, a sugar-like syrup is produced. 1 This reaction, discovered in the late nineteenth century, has been thoroughly investigated 2 with the goal of obtaining carbohydrates with total synthesis in the food industry and astronautics. These complex mixtures of sugars and branched-chain sugars, produced from formaldehyde with self-condensation, are called formose. There are many well-known procedures for obtaining various product mixtures and, sometimes, for selective isolation of single substances; these procedures involve variation of the reaction conditions--specifically, the solvent [water, short-chain alcohols, N,N-dimethylformamide (DMF)], the catalyst, and added materials, as well as the temperature and the pressure. Contrary to the thermally induced polymerization reactions 3 of formaldehyde or the action of acids, the base-catalyzed process is an aldol reaction for the production of glycolaldehyde 2 CH20 ~ HOCH2CHO

4

T


which can be detected in formose mixtures obtained under various conditions. Glycolaldehyde exerts an autocatalytic effect 4 on the process; similar reactions of other hydroxyaldehydes and endiol compounds have also been reported. 5 In certain cases addition of fructose or glucose to the reaction medium results in the formation 6 of formose mixtures with specific composition. Selective formation of C-hydroxymethylglycerol can be achieved by the addition of 2-diethylaminoethanol catalyst and a hexose, and the rate of conversion is strongly influenced 7 by the configuration of the added aldose and deoxyaldose. The catalysts commonly used in the formose reaction are shown in Table 1.1. A basically simple reaction scheme of the formose reaction, as described by Pfeil and Ruckert, 8 is illustrated in Figure 1.1. The formose reaction leads to the possible formation of stereoisomeric sugars, and yields of the isolation of individual substances are essentially dependent on the specific reaction conditions. Standardized procedure for the preparation of the formose mixture 8 To a 30% aqueous formaldehyde solution (45 ml) water (225 ml) is added; the mixture is warmed up to 60~ in a thermostat and Ca(OH)2 (5.0 g) is added when the alkaline content of the mixture reaches 0.22 M. Then samples are taken from the solution: first (because of the low conversion rate) 10 ml and then 4 ml. The samples are quenched with dilute formic acid and rendered salt-free by passing through an ionexchange column. Freeze drying of the 10 to 15-ml eluants gives mixtures consisting of the condensation products and paraformaldehyde, which are separated by extraction with cold water. The extract is chromatographed by applying the upper phase of a 4 : 5 : I mixture of n-butanol-glacial acetic acid-water as the developing system, with anilinephthalate as the visualizing agent.

The primary product of the formose reaction is glycolaldehyde (1.1), which is further transformed in essentially two ways, depending on the reaction conditions9: 1. Under practically neutral conditions (e.g., CaCO3) the glycolaldehyde produced in the formose reaction does not undergo dimerization into tetroses (1.2); instead, addition of a

T A B L E I.I

Catalysts for the Formose Reaction

Mineral compounds

Organic bases

Ba(OH)2, Ca(OH)2, Mg(OH)2, Pb(OH)2, Sr(OH)2, LiOH, NaOH, KOH, T1OH, rare-earth hydroxides, BaCO3, CaCO3, MgCO3, MgSO4, CrO3, MgO, PbO, TiOe, V205, Ag20, MOO3, ThO2, A1203, ZnO, WO3, kaolinite

Pyridine, picolins, collidine, 2-dimethylaminoethanol, triethanolamine, tetraethylammonium hydroxide, thiamine, (benz)thiazolium salts, N-methylmorpholine, ion-exchange resins of strong basic character, N-methylpiperidine

I.I. BUILDUPWITH TOTAL SYNTHESIS

5

c2

HCHO

CHO

I

1.1

1.2

CHOH I CHOH I CHOH I CH2OH 1.5

CHOH i CHOH I CHOHI I CH2OH 1.6

CH2OH

CH2OH

i

I

CHOH

I

f

CH2OH

CHOH

CHO

CHO

c1

CHO

i

CHOH i CH2OH c1

CHOH I

CH20 H 4

1b CH2OH C=O I

CH2OH 1.3

c]

i

CHO

C-O

C=O ,. 9 i "- CHOH

I

CHOH t

CHOH

t

CH2OH c2

I

CH2OH ,~ 1.4

c1

CHOH i CHOH I CHOH t CH2OH

CH20 H

CH2OH CHOH i

i

C=O i CHOH i CH2OH

CH2OH

C=O i

1L

CHOH

I

CHOH i HQCH2---C-OH

o.21ol.

1l

I C3k

~H2OH C=O

I

C=O

i CHOH i CHOH t CH2OH

C 1= formaldehyde C2= glycolaldehyde C3k = dihydroxyacetone FIGURE

I. I

third formaldehyde molecule results in dihydroxyacetone (1.3). The reaction of this latter compound with glycolaldehyde gives ribulose (1.4), which is the final product when CaCO3 is added, and it undergoes further transformation into ketopentoses or aldopentoses only after an elongated reaction time.

6

I ASCENDINGSYNTHESISOF MONOSACCHARIDES

2. Under more alkaline conditions (e.g., addition of CaO) glycolaldehyde is converted into a mixture of tetroses, which are rather unstable under the given conditions and are transformed into triose (1.3)-pentose (1.5) mixtures. Hexoses (1.6) are produced by the dimerization of dihydroxyacetone, which is possible only under more alkaline conditions, since, in the presence of CaCO3, dihydroxyacetone gives tetrulose with glycolaldehyde. Further transformations by aldol-type condensation are inhibited by quick ring closure into furanoses or p y r a n o s e s ~ s t a r t i n g with the pentoses produced in the reaction. Except for the first step (the formation of glycolaldehyde), each step of the formose reaction is an aldol condensation, which is a reversible process. The condensation reactions leading to open-chain products are more favorable than those giving rise to branched-chain substances. The conversion of formaldehyde into sugars is promoted by alcohols, and this is explained by the reduced base dissociation, and thus the inhibition of the Cannizzaro reaction. Formose reaction in aqueous methanol 9 To a stirred mixture of 30% aqueous

formaldehyde (200 ml) and methanol (200 ml) CaO (3 g) is added. When the vigorous reaction has subsided, the mixture is kept at 40~ for 40 min, until the conversion of formaldehyde is complete. The pale-yellowsolution is filtered through a glass filter, and the filtrate is acidified with dilute sulfuric acid and quickly neutralized with BaCO3. The precipitate is filtered, the filtrate is concentrated at 4 tort pressure, and the sweet syrupy residue is chromatographed with a 5:3:1:3 n-butanol-pyridine-benzene-water developing system, with anilinephthalate as the visualizing agent. For the preparation of larger quantities of formose, preliminary investigations have been carried out to ensure the application of the formose mixture as a sugar source. Figure 1.2 summarizes the methods reported 1~ for the production of larger quantities of formose. According to experience gained from the hydroformylation reaction 11 of formaldehyde (when the intermediate is also glycolaldehyde), this process also involves the formose reaction, with the production of nonbranched sugars. However, this reaction is essentially different from the transformations discussed a b o v e - - t h e addition of the "synthesis gas" (CO+H2) on formaldehyde is executed in pyridine in the presence of bis(triphenylphosphine)carbonyl rhodium(I) catalyst. 12 The consecutive reactions proceed as shown in Figure 1.3: Depending on the selected route of transformation, various organic bases are used as catalysts for the conversion. General procedure 12 for the preparation of simple sugars from formaldehyde and "synthesis gas" A solution of paraformaldehyde (622 mg, 20 mmol), bis(triphenylphosphine)carbonyl rhodium(I) chloride (69 rag, 0.1 mmol), and the tertiary amine (see Table 1.1) in pyridine (10 ml) is placed to a 54-ml stainless-steel autoclave and a pressure of 120 at of the "synthesis gas" (H2/CO = 2) is applied. The reaction

I.I. BUILDUP WITH TOTAL SYNTHESIS

'~

500 g of 37% formaline (d = 1.1141) 21 liters of water 200 ml of methanol 50-60oc 30 g of Ca(OH)2 , stirring for 20 rain (the solution turns yellow) Add 160 ml of 20% HzSO4 until the reaction mixture becomes slightly acidic Residue

Filtrate

Neutralize with powdered CaCO3, heating at 80~ for 30 rain, clarifying with activated-carbon Residue

Filtrate Concentrate g-]-6 1 of its original volume in vacuo. Apply a column ofIR-120B (H§ (2-liter column, washing 3 times with water) Apply a column of IR-400 (OH-)-resin (2-liter column, washing 3 times with water)

Elution 116 g of formose syrup (80%) FIGURE 1.2

is complete in 30 min at 120~ when the cooled autoclave is opened and the reaction mixture is examined by thin-layer chromatography (TLC). The results are summarized in Table 1.2. I n s t u d i e s of t h e v a r i o u s f a c t o r s i n f l u e n c i n g t h e f o r m o s e r e a c t i o n , t h e i n f l u e n c e of t e m p e r a t u r e w a s f o u n d t o b e v e r y i m p o r t a n t a n d i n t e r e s t i n g . B y c o n d u c t i n g t h e C a ( O H ) z - c a t a l y z e d p r o c e s s at 98~ i n v e s t i g a t o r s f o u n d that the reaction was no longer autocatalytic and the product distribution w a s m o r e s i m p l e . D e t a i l e d s t u d i e s h a v e s h o w n 13 t h a t at 18% c o n v e r s i o n C6

CH,_O + CO + H:

"-)

HOCH2CHO

CH20 + H 2

--)

CH30H

2 CH20 + CO + Ha

"-)

C3H603

2 CH20 + 2CO + 2H:

--)

C4H804

2 CHzO + 2CO + 2Hz

--)

CsUl005

3 CH20 + 3CO + 3H 2 --)

C6H1206

FIGURE i.3

I ABLE 1.2 Preparation of Simple Carbohydrates by Reaction of Formaldehyde with "Synthesis Gas" in Presence of Bis[Triphenylphosphinecarbonyl Rhodium(l)] CatalystI2

Yield (%) Cocatalyst (amine, mom)

Overall yields,

Triethylamine (0.04) Triethylamine (0.1) Triethylamine (0.2) Triethylamine (0.2)' Triethylamine (0.2)d Triethylamine (0.4) Quinuclidine (0.2) N,N-Dimethylbenzylamine (0.2) N-Methybenzylamine (0.2)

C:=3

aCH30H + C, b~um of glycolaldehyde plus ethylene glycol

(%)O

I.I. BUILDUP WITH TOTAL SYNTHESIS

9

monosaccharides are produced with excellent selectivity, glucose is the predominant product, and no branched-chain sugars are present. If the reaction is not quenched at this stage, saccharinic acids are produced, the formation of the products of the Lobry de Bruyn-Alberda van Ekenstein rearrangement is observed, and branched-chain sugars and sugar alcohols are also formed in Cannizzaro and crossed Cannizzaro reactions. ~4 Further selectivity can be achieved by application of nonaqueous solvents. Previous works (see Chapter 1, Ref. 15) have demonstrated that alcohols inhibit the Cannizzaro reaction. Thus, the formose reaction can be executed as low as at 0.05 C a O : H C H O composition, and contrary to that observed for water, the increase of the concentration of formaldehyde results in the growth of the yield of the sugar, which is 57% when the reaction is conducted at 60~ for 1 h with 0.15 M/liter of CaO and 5 M of formaldehyde. ~6 Preparation of methanolic formaldehyde solution 16 After 200 g of paraformaldehyde is dissolved in 400 ml of dry methanol, the solution is boiled for 7 h. The formaldehyde content of the filtered solution is 12 M.

If the formose reaction is performed in an aqueous solution, production of large quantities of sugars can be achieved by keeping the concentration of formaldehyde low (

CH2OH I HO_C--CH20 H I CH20H

CH2OH C--O I CHOH I CH2OH

CHO I

L-A

CHOH I CHOH I

CH2OH

4.1

C2, A

I CI'A

CliO I CHOH t CHOH I HO--C--CH2OH

CH20H I CHOH I C--O I CHOH

I

I

C-'H2OH

CH2OH

Cl'A CH2OH

I

I

HO--C--CH2OH I

CH2OH

CH2OH

CHOH I HO--C--CHO I CHOH I

CH2OH l gC

I 2C1'A

CliO HO--C--CH2OH I CHOH

I CI'A

gC

I

CH2OH I CHOH

CH2OH

I

HO--C--CH2OH I > CHOH

gC
x y l o > ribo > lyxo. Aldolization oftrioses 38 A solution of D,L-glyceraldehyde(6 mg) or glycolaldehyde (14 mg) and D,L-glyceraldehyde (6 mg) and the catalyst (see Table 1.5) in 4 ml of water is kept at room temperature for 45-60 min. The mixture is then neutralized with Dowex 50 W (H§ cation-exchange resin and filtered, and the

TABLE 1.5 Diastereomeric Ratio Observed in Aldol Condensation of Trioses and in Condensation of Glycolaldehyde and D,c-Glyceraldehyde Diastereomeric ratio (%) 2-Hexuloses

Aldopentoses

Concentration of catalyst

ara

xylo

ribo

lyxo

ara

xylo

ribo

lyxo

LiOH 0.01 M NaOH 0.01 M Ca(OH)2 0.01 M Sr(OH)2 0.01 M Ba(OH)2 0.01 M

55 54 50 57 50

29 34 30 29 33

11 10 14 11 13

5 2 6 3 4

58 60 54 61 65

29 28 28 28 23

10 9 15 8 9

glycerol (13.1) with excess of the reagents potassium cyanide, sodium iodide, and sodium hydrogen carbonate. Then the resulting syrupy, distiUable product (13.2) was subjected to deprotection with hydrogen chloride in methanol, furnishing 2-deoxy-o-glycero-tetrononitrile(13.3) (Fig. 1.13): Preparation of 2-deoxy-D-glycero-tetrononitrile (13.3) from 2,3-O-isopropylidene-l-O-(p-tolylsulfonyl)-D-glycerol (13.1) 1 A suspension of 13.1 (1.69 g, 5.9 mmol), dry KCN (1.92 g, 29.5 mmol), NaI (4.43 g, 29.5 mmol) and NaHCO3 (4.96 g, 5.9 mmol) in dry dimethylsulfoxide (Me2SO) (distilled from Call2) is stirred at 80~ for 2 h in the absence of moisture. After cooling, the reaction mixture is poured into water (230 ml) and extracted with ether (4 • 50 ml). The combined organic extract is washed with aqueous NaHCO3 (2 • 30 ml), dried (MgSO4), and evaporated under reduced pressure. The crude product (0.636 g) is purified by column chromatography (eluant CHC13) on Kieselgel (30 g). Evaporation of the olive-green eluate gives 0.543 g of 13.2, b.p. 60~ (133 Pa), [a]~ -5.44 (c = 9.4 in CHC13). A solution of nitrile 13.2 (0.54 g, 3.83 mmol) in dry methanol (105 ml) is cooled to 0~ 1.87 M HC1 in methanol (2.15 ml) is added with stirring, and the mixture is refrigerated (7~ for 20-24 h. It is cooled to 0~ dry ammonia gas is passed through the solution until alkaline (for litmus paper), and the solvent is evaporated. The residue is dissolved in acetone (7 ml), NH4C1 is filtered off and washed with acetone (4 ml), and the combined filtrate is evaporated under diminished pressure. The residual syrupy 13.3 {(0.348 g, 90%), [a]2o4 +20.58 (c = 6.5 in EtOH)} is not further purified.

A similar result was obtained 2 with 2,4-di-O-ethylidene-l-iodo-Derythritol (14.1) in which treatment with an equimolar quantity of sodium cyanide (Fig. 1.14) gave rise to 2-deoxy-3,5-O-ethylidene-o-ribononitrile (14.2), whose catalytic hydrogenation afforded 2-deoxy-D-ribose (14.3).

> O

L-~o 14.1

OH3

DMF

O

>

OH

O

CH 3

14.2

FIGURE

I 14

2) H 2 / PtO 2

OH

OH 14.3

32

I ASCENDINGSYNTHESISOFMONOSACCHARIDES

This procedure was found suitable for preparation of 1-14C-labeled 2-deoxy-D-ribose, as well. 2 An analogous procedure, involving the reaction of 2,3:4,5-di-Oisopropylidene-l-O-(p-tolylsulfonyl)-D-arabinitol (15.1) with sodium cyanide, followed by reduction of the resulting 2-deoxy-3,4:5,6-di-Oisopropylidene-I>arabino-hexononitrile (15.2) with diisobutyl aluminium hydride (Fig. 1.15), allowed the preparation 3 of 3,4:5,6-di-O-isopropylidene-2-deoxy-D-arabino-hexose (15.3), thus offering a convenient route to 2-deoxy-o-arabino-hexose. Functionalized derivatives of this latter sugar have served as key intermediates in syntheses of the aminodeoxyhexose components of various antibiotics. 4 A similar extension can also be executed at the other, nonreducing end of the carbon chain of partially protected aldose derivatives. Thus, primary sulfonates and terminal anhydro derivatives have been converted with alkali cyanides into the corresponding deoxyurononitriles extended with one carbon atom in the chain. In the case of the anhydro sugar 16.1 (Fig. 1.16), water was found the best solvent to prepare 5 the heptofuranurononitrile 16.2. Preparation of 1,2-O-isopropylidene-6-deoxy-a-D-gluco-heptofuranurononitrile (16.2) 5 A mixture of 1,2-O-isopropylidene-5,6-anhydro-a-D-glucofuranose (16.1)

a2c

.fc>

~

O802~0H3

~

"-'

H2C--CN NaCN

H 3 C ~ > H3C" -~O ~ -O .OH3 ,,__.O~" CHa 15.2

15.1

' DIBAL

H2C--CHO H3C~o H3C

O

CH3

L_oXc. 15.3 F I G U R E 1.15

1.2. BUILDUPOF SUGARSWITH ASCENDINGSYNTHESIS [ CHOH I CH#--O--SO2R

~'~O

CN-

I CHOH I CH~--CN

>

" KCN/H20

>

.o Co

~'H "~O

"

CH3

OL H

CN"

/ ~

"---'

O

o:,.]

OH

KCN

CN I .CH2

.o-1/x, L___O

i|

CHa

17.1

17.2 FIGURE 1.17

17.3

34

I


for 2 days and then equilibrated with ---7.5 ml of acetic acid. Potassium tosylate is filtered off and washed with methanol (100 ml), the combined filtrate is evaporated to dryness, and the residue is recrystallized from water (70 ml), to obtain 17.3 (29.4 g, 93%), m.p. 129~ After repeated recrystallization, the pure product has m.p. 133~ [o~]~ +25.5 (c = 2.2 in pyridine). F u n c t i o n a l i z a t i o n of the t e r m i n a l hydroxyl group and chain e x t e n s i o n with alkali c y a n i d e can be conveniently e x e c u t e d in a o n e - p o t o p e r a t i o n . F o r e x a m p l e , m e t h y l 2,3,4-tri-O-acetyl-6-deoxy-c~-D-gluco-heptopyranurononitrile (18.2) was readily o b t a i n e d 7 f r o m the c o r r e s p o n d i n g C-6 h y d r o x y c o m p o u n d : m e t h y l 2,3,4-tri-O-acetyl-a-D-glucopyranoside (18.1) according to a simple p r o c e d u r e shown in Figure 1.18.

Preparation of methyl 2,3,4-tri-O-acetyl-6-deoxy-a-D-gluco-heptopyranurononitrile (18.2) from (18.1)7 A solution of methyl 2,3,4-tri-O-acetyl-a-o-glucopyranoside (18.1) (9.6 g, 0.03 mol) and triphenylphosphine (7.9 g, 0.03 mol) in CC14 is refluxed for 15 min and diluted with Me2SO (100 ml). The volatile components are then removed by distillation from a steam bath, so that the volume of the distillate is --45 ml in the collector flask. Then, NaCN (2.5 g) is added to the residual mixture and the solution is warmed for 1.5 h. It is then poured into water (---800 ml) and kept at 25~ The precipitated solid is filtered off, washed with cold water several times, and dissolved in hot methanol. The solution is filtered while hot and concentrated, and the residue is recrystallized from methanol. The crude product (4.5 g) is dissolved in CHC13, and petroleum ether is added until separation of crystals is observed. The product 18.2 has m.p. 132-133~ [a]~ + 147 (c = 0.7 in CHC13). T h e 2 - d e o x y a l d o n o n i t r i l e derivatives p r e p a r e d f r o m suitably functionalized m o n o s a c c h a r i d e s with p o t a s s i u m cyanide are listed in T a b l e 1.7. 8-18 A n alternative, but less f r e q u e n t l y utilized r o u t e to r e l a t e d e x t e n d e d chain 2 - d e o x y a l d o n o n i t r i l e s is b a s e d on the raction of aldose diethyl dithioacetals with a 2.5 m o l a r excess of in situ-generated I C N to afford 19 a d i a s t e r e o i s o m e r i c m i x t u r e of 2-ethylthio-2-deoxyaldononitriles e l o n g a t e d by one c a r b o n a t o m (Fig. 1.19). T h e n c h e m o s e l e c t i v e r e d u c t i o n of the ethylthio g r o u p over R a n e y nickel catalyst allowed the isolation of the t a r g e t 2-deoxyaldononitriles. Finally, the p r o d u c t s o b t a i n e d on chain e x t e n s i o n with n i t r o m e t h a n e (see Section 1.2.3) are also suitable for p r e p a r a t i o n of aldononitriles elong a t e d by one c a r b o n a t o m in the sugar chain, w h e n the saccharide carrying the i n t r o d u c e d / 3 - n i t r o e t h a n o l unit is subjected to the r e a c t i o n s e q u e n c e

"

AcO~

Ac

KCN / DMSO

>

Ac

OAc

OAc

18.1

18.2 FIGURE

1.18

TABLE 1.7 2-Deoxycarbononitriles Derived from Monosaccharides by Treatment with Potassium Cyanide Educt

Product

~o~O~o o~ --OTs

; -~CH3 O~o B

HO-~C(~

~

O-~CH 3 OH3

-- OTs

~~ o

45

syrup

--

8

96

--

--

9

90

syrup

-62.4

5

Ref(s).

~~o

(c = 0.75, C H C l s )

; - - ' ~ ca 3 OH3

CN

~~176 CH3

HO--I O

~o

CH3

~co_~Co~

~o

76

/_oo~

j_c;

Mso~Bn . ~ O B n

+4.3 (c = 3, p y r i d i n e )

10

152

+12.9 (c = 2, p y r i d i n e )

10

syrup

--

CH3

CH2OTs O~CH 3 ?O/~'CH3

FO~'CH3 L__oXcH3

129

CH3

CN I OH2 O~CH 3 i___o/--CH3

FOT~

[r

O@CH 3 OH3

OH3

~OTs

~or o.~ o,~ CN

Yield M.p. (%) (~

21

3

I---O~ "cH3 L__O~'CH3

Mso(~Bn ~ ' O B n

c~

T~O~~oc~ T~O~ ~ ~oc~3 OBn

OBn

(continues)

:]6

I ASCENDING SYNTHESISOF MONOSACCHARIDES

TABLE

(continued)

1.7

Educt

Yield M.p. (%) (~

Product

yc~~

I OAc

Ac

OAc

c0:~o~ '

H

CN

O GIla OH3

Br O

~ OCH3

H3CcH3

+82 (c = 0.45, CHC13)

28

61-63

-67.7 (c = 0.85, CHC13)

75

syrup

+44 (c = 11, CHC13)

13

syrup

+168 (c = 0.3, CHC13)

13

syrup

+85 (c = 1.6, CHC13)

78

91-93

+152 (c = 1, CHCI3)

68

syrup

+134.7 (c = 0.11 CHC13)

O@CH 3

BzO "

f OCH3

OCH3

)-c~~

Br O

f OCH3 OCH3

MEMO "

BnO "] " OCH3 OBn

f OCH3

OCH3

fc~~

~_o2

~0n~

OH3

j~cL

OCH3

MEMO "

204-6

C6H5

:6H5

"

BzO "~

12

54

O--

[--Io

HaCc~H3

f OCH3 OAc --CN

Ref(s).

c SHs~:~O

O~

O

135"135.5 +139 (c = 1.88, CHC13)

~t,c~

AcO "~

CH3

laid

BnO~ I BnOJ~oCH3 OBn

!

)-C"o

o~ocIBr O?O OCH 3

Bn

CH 3

FI H3C'N~O

~

.~C/~o ..(

BnO ~

ct

OCH 3

OCH3

OCH3

, , ~-CN H3C/O

.~C--o

15

c,

(continues)

1.2. BUILDUP OF SUGARS WITH ASCENDING SYNTHESIS

(continued)

T A B L E 1.7

Educt

Yield M.p. (%) (~

Product

CN

CHy--OH ~OBn

I

CH2 OBn

OH3 o~CH 3

o-@c~

N3~ , , , ~ O Ph2ButSiOj

~

OH

Ph2ButSiOJ

Ph2ButSiO~J

~OTf

. o-~CH~ N3~ 0 z

-30.8 17 (c = 0.40, CHC13)

63

syrup

-15.2 (e = 1, CHC13)

73

syrup

,,

H

O ~

H

OH3 OH3

Ph

CH3

H

_ H

0

O~~~___OH3

CN

_ / ON -= H

H H P/h

syrup

Ph~ButSiO

./.I

_

60

~~.~C N CH3

CHa

o~CH~

H

syrup

CI

OH3

,"

28

OBn

b

CI

- - O

Re[(s).

BnO--~

OBn

H

[~]D

b

BnO

-

~I

j

Ph

+6.1

(c = 1.4, CHC13)

O H

0

~---r q

O~CH3 OH3

(continues)

I ASCENDING SYNTHESIS OF MONOSACCHARIDES

38

(continued)

T A B L E 1.7

Yield M.p. Educt

Product

Ho4-'~ O@CH OH 3

Vc\ ~?Ac AcO ~

(%) (~

[~]o

92

126

-50.2 (c = 20.75, CHC13)

50

210

+108.3 (c = 1, CHC13)

10

81

147

+17.5 ~ 50.5 (end value) (c = 2, H2O)

10

66

182

-27.5 (c = 2, CHC13)

10

90

144

Ref(s).

3

OH 3

//~ ( OAc /

;-c. ~

F C N o OH

. (,re 3

AcO "~

OAc

CH 3

(OAc OAc

o4,,y

H

1

OH

O OC6H5

FCNo OH

AcO ~

(

OAc

f

00CH 3

OH

AcO "

~tc"~3

Bzo ,,

(ocm

OCH 3

CN

80

syrup

+99 (c = 4.6, CHC13)

91

125

+63 (c = 2.5, pyridine)

91

90

-29.6 (c = 2, pyridine)

~c.~/~

HO "~

( OCH3

CN OH2

O

H

HO C6H5

F

OAc

AcO_~---O~ H L

O"

C6H5

CN

CN

I CH2

I

OH2 OAc

F

co_F~ O"

C6H5

13

OCH 3

I

I

OH 2

L

," I OAc

)_c;

j-c• ~

10 -12.5 (c = 2, CHC13)

F OAc OAc

h

ACOLoAc

6


39

CN HC(SC2H5) 2

ICN

I

CHOH

CN

I

CH(SC2H5)2 I CHOH

1

Raney Ni

~

OH 2

>

CHOH

I

I

FIGURE Glyc-CHO

+

I

1.19 >

CH3NO 2

Glyc--CHOH--CH2NO 2 NaOAc / Ac20

Glyc--C--CN II OH 2

43

NO2 O H

0oc

OH3

OH3 OH3

24.1

24.2 FIGURE

1.24

plished at 0~ (Fig. 1.24). Both isomers are produced if the dialdehydosugar with D-ribo configuration is employed, or the reaction is executed at higher temperatures. A very efficient procedure 12 reported for the synthesis of the two rare sugars L-glucose and L-mannose is based on a related methodology. A typical example for the nitromethane-condensation is the chain extension of D-galactose (Fig. 1.25) to obtain 1-deoxy-l-nitro-D-glyceroL-manno-heptitol (25.1) and 1-deoxy-l-nitro-D-glycero-L-gluco-heptitol

(25.2). 1-Deoxy-l-nitro-D-glycero-L-manno-heptitol (25.1) and 1-deoxy-l-nitro-D-glycero-L-gluco-heptitol (25.2) 13 To a suspension of D-galactose (50 g) in dry methanol (10 ml) and nitromethane (130 ml) a cold solution of sodium methoxide (prepared from 13 g of sodium and 300 ml of methanol) is added. The mixture warms spontaneously to 50~ and after stirring for 1 day it is cooled to -20~ then the sodium salts of the deoxynitroheptitols are filtered off and washed with methanol. The wet salt mixture is dissolved in water (500 ml) and deionized by passing through a column filled with Amberlite IR-100 cation-exchange resin. The eluate is concentrated, the separated crystals are filtered off, and the addition of ethanol to the syrupy residue gives further crystalline material. Recrystallization of the less soluble crystalline product from water leads to the isolation of 13.3 g (18.4%) of the L-manno-heptitol 25.1 in the form of monohydrate, m.p. 158-159~ After drying over phosphorous pentoxide for 24 h, the anhydrous product has m.p. 165-166~ [a]~ +6.3 (c = 4 in water). Recrystallization of the more soluble crystal fractions first from aqueous ethanol and then from ethanol gives 4.5 g (6.6%) of a product mixture (m.p. 147-

CH2NO 2 --OH

D-Galactose NaOCH 3

CH3NO2

CH2NO2 HO

--OH

OH

HO--

HO

HO--

HO --OH

OH

CH2OH

CH2OH

25.1

FIGURE 1.25

25.2

44

~ ASCENDING SYNTHESIS OF MONOSACCHARIDES

152~ and 16.6 g (24.8%) of the L-gluco-heptitol (25.2), m.p. 152-153~ (c - 4 in water).

[c~]2o~ +7.8

o-Glycero-L-gluco-heptose 11 In this procedure 2 g of 1-deoxy-l-nitro-o-glyceroL-gluco-heptitol is dissolved in 1 N sodium hydroxide (10 ml), and this solution is added dropwise to a solution of concentrated sulfuric acid (1.2 ml) dissolved in water (1.6 ml) at 50~ After stirring for a few minutes, the reaction mixture is deionized by passing through columns filled with Amberlite IR-120 (H § and Duolite A-4 (OH-) ion-exchange resins. The eluate and the washings are concentrated in vacuo and mixed with a solution of phenylhydrazine (1.2 ml) in 25% acetic acid. Separation of the phenylhydrazone starts in a few minutes, and after remaining overnight the product is filtered and washed with cold water and ethanol to give 1.8 g (78%), m.p. 191-192~ Conventional treatment of the phenylhydrazone with benzaldehyde and seeding gives pure o-glycero-L-gluco-heptose monohydrate, m.p. 83-85~ [c~]~ -13.7 (c = 4 in water, in equilibrium). D e t a i l e d i n v e s t i g a t i o n s h a v e s h o w n t h a t in c e r t a i n c a s e s M e 2 S O , as t h e s o l v e n t , h a s a f a v o r a b l e e f f e c t o n t h e y i e l d of t h e t r a n s f o r m a t i o n , as s h o w n b y t h e e x a m p l e of t h e c o n d e n s a t i o n of o - g a l a c t o s e w i t h n i t r o m e t h a n e . 3'14

Condensation of o-galactose with nitromethane in Me2SO To a solution of Dgalactose (40 g) in DMSO (350 ml) and nitromethane (105 ml), anhydrous calcium sulfate (15 g) and 12% methanolic sodium methoxide (250 ml) are added. After remaining for 4 h, the aci-nitro salts are precipitated by the addition of ether (dried over sodium) at 4~ then the creamy precipitate is filtered with suction, washed well with ether, and extracted with water. Following removal of insoluble CaSO4 the filtrate is passed through a column filled with Amberlite IR-120 (H +) resin and concentrated to result in the crystallization of the monohydrate of 1-deoxy-l-nitroD-glycero-L-manno-heptitol (25.1), and sometimes an orange syrup is also separated. The physical data of the pure product, recrystallized twice (16.5 g, 30%), are m.p. 155-157~ and [a]D +6 (C -- 2 in water). The orange syrup can be crystallized from a small volume of ethanol, and after repeated recrystallization pure 1-deoxy-1nitro-D-glycero-L-gluco-heptitol (25.2) (4.8 g, 9%) is obtained, m.p. 152-153~ [a]2o4 +7.7 (c-- 2 in water). C o n d e n s a t i o n of 2 , 5 - a n h y d r o - 3 , 4 , 6 ' t r i - O - b e n z y l - o - a l l o s e (26.1) w i t h nit r o m e t h a n e (Fig. 1.26) s h o w e d t h a t u n d e r k i n e t i c c o n t r o l t h e r e a c t i o n afforded a single product: 3,6:anhydro-4,5,7-tri-O-benzyl-l-deoxy-l-nitro-oglycero-D-altro-heptitol (26.2). 15'16

3,6-Anhydro-4,5, 7-tri-O-benzyl-l-deoxy-l-nitro-o-glycero-D-altro-heptitol (26.2) 16 To a stirred, cold (0~

,nO--O.j"O

+

mixture of 2,5-anhydro-3,4,6-tri-O-benzyl-o-allose

NaOCH 3 CH3NO 2

OBn OBn

>

BnO~

r Ho-j

OBn OBn 26.2

26.1

FIGURE 1.26

NO


45

(26.1) (2.77 g, 6.4 mmol) in methanol (200 ml) and nitromethane (20 ml), 10 ml of 0.48 M sodium methoxide in methanol is added dropwise, and after stirring at 0~ for 1 h, it is neutralized with Dowex 50 (H +) resin, filtered, and concentrated. The residue is dissolved in chloroform, and washed with water and the organic layer is dried. After removal of the solvent by distillation under reduced pressure the residue is crystallized from ether by the addition of hexane to give 2.35 g (74%) of 26.2, m.p. 42-44~ [cr -12.4 (c = 0.18 in chloroform).

On treatment of 1-deoxy-l-nitroalditols with hydrogen peroxide in aqueous solution and in the presence of catalytic amounts of molybdate, tungstate, or vanadate ions, the corresponding aldoses are produced, but no such conversion proceeds in the absence of these catalysts. 17 The transformation of the nitrohexitol (27.1) derived from L-arabinose into the rare, unnatural sugar L-mannose (27.2) is shown in Figure 1.27. Preparation of L-mannose (27.2) 17 To a solution of the sodium salt of the nitrohexito127.1 derived 18from L-arabinose (15 g) in water (120 ml), sodium molybdate (0.25 g) is added and then gradually treated with a 15% hydrogen peroxide (40 ml) solution to ensure that the temperature of the reaction mixture does not rise over 30~ It is kept at room temperature for 20 h, 0.2 g of 5% Pd/C is added, and the mixture is allowed to remain for an additional day. After filtration, a solution of phenylhydrazine (11 ml) in methanol (20 ml) is added and theprecipitated L-mannose phenylhydrazone (13 g, 48%), is filtered off after ---5 h.

The nitromethane syntheses with aldoses and aldehydo-saccharides, reported in the literature thus far, are summarized in Table 1.8. 20-64 The reaction conditions employed for the nitromethane syntheses listed in Table 1.8 were used to ensure that the major product of the chain extension was the required 1-deoxy-l-nitro-alditol, since earlier studies had revealed that application of either milder conditions or a longer reaction time may result in the formation of secondary products, which are mainly the anhydro derivatives of the 1-nitroalditols. These latter substances could be readily isolated when a concentrated aqueous solution of the C-2 epi, meric mixture of the open-chain deoxy-nitroalditols (the primary products of the nitromethane addition) was subjected to boiling for a longer period of time (20-30 h). Under such circumstances a slow ring closure occurs with the formation of the 2,6-anhydro derivatives, of which the thermodyCliO

HC---- NO 2 Na OH OH HO

'

H202

OH

Na2MoO 4

HO

OH

HO HO OH

OH

27.2

27.1 FIGURE

1.27

TABLE 1.8

Nitromethane Syntheses with Aldose Derivatives

A

OQ

Educt

Nitroalcohol(s)

D-Glyceraldehyde 2,3-0-Isopropylidene glyceraldehyde D-Erythrose

1-Deoxy-1-nitro-D-erythritoland -threitol

Aldose

1-Deoxy-1-nitro-D-arabinitol and -ribit01

1-Deoxy-1-nitro-L-arabinitoland -ribit01 3,s-0-Benzylidene-1-deoxy-1-nitro-D-arabto and -ribit01 3,5-0-Ethylidene-1-deoxy-D-arabinitol and -ribit01 1-Deoxy-1-nitro-D-mannitol and -D-glucitol

1-Deoxy-1-nitro-L-mannitol and -L-glucitol

1-Deoxy-3,5:4,6-di-0-ethylidene-1-nitro-~idito and -L-glucitol 4,6-0-Benzylidene-1-deoxy-1-nitro-D-mannitol 2,4-0-Benzylidene-6-deoxy-6-nitro-D-glucitol 1-Deoxy-1-nitro-D-glucitol D-Lyxose 1-Deoxy-1-nitro-D-allitoland -D-altritol D-Ribose 2,3-0-Isopropylidene-D-ribofuranose 1-Deoxy-1-nitro-3,4-0-isopropylidene-D-alttol and -D-allitol 1,6-Dideoxy-1-nitro-D-gulitol and -D-iditol 5-Deoxy-D-xylose 1,7-Dideoxy-1-nitro-L-talo-heptitol D-Rhamnose 1,2-0-Cyclohexylidene-a-D-xylo-pentodialdo-1,4- 1,2-O-Cyclohexylidene-6-deoxy-6-nitro-a-~-glucofuranose and -P-L-idofuranose furanose 1,2-0-Isopropylidene-a-D-xylo-pentodialdo-1,4- 6-Deoxy-1,2-0-isopropylidene-6-nitro-a-wghduranose 6-Deoxy-6-nitro-D-glucose and -P-L-idofuranose furanose and -L-idose 3-O-Alkyl-6-deoxy-l,2-O-isopropylidene-6-nitro-a-o3-0-Alkyl-1,2-0-isopropylidene-a-D-xyloglucofuranose and $3-L-idofuranose pentodialdo-1,4-furanose 6-Deoxy-1,2-O-isopropylidene-3-O-methyl-6-nitro-a-~1,2-0-Isopropylidene-3-0-methyl-a-D-xyloglucofuranose and -P-L-idofuranose pentodialdo-1,4-furanose

ReMs).

3-0-Benzyl-1,2-0-isopropylidene-a-D-xylopentodialdo-1,4-furanose 3-0-Benzyl-1,2-0-isopropylidene-a-D-ribopentodialdo-1,4-furanose 3-0-Benzyl-1,2-0-isopropylidene-0-L-arabinopentodialdo-1,4-furanose Ethyl 2-acetamido-2-deoxy-1-thio-a-D-xylopentodialdo-1,4-furanose Differently protected aldehydoaldoses D-Allose

3-O-Benzyl-6-deoxy-I,2-O-isopropylidene-6-nitro-~Lidofuranose and -a-D-glucofuranose 3-O-Benzyl-6-deoxy-1,2-O-isopropylidene-6-nitro-~talofuranose and -or-D-allofuranose 3-O-Benzyl-6-deoxy-1,2-O-isopropylidene-6-nitro-~-~altrofuranose and -a-D-galactofuranose Ethyl 2-acetamido-2,6-dideoxy-1-thio-6-nitro-a-Dglucofuranoside and 0-L-idofuranoside Protected nitroalcohols 1-Deoxy-1-nitro-D-glycero-D-allo-heptitol and 7-Deoxy-7nitro-D-glycero-L-allo-heptitol I-Deoxy-1-nitro-D-glycero-D-gluco-heptitol and -D-mannoheptitol 1-Deoxy-1-nitro-D-glycero-D-gulo-heptitol 1-Deoxy-1-nitro-D-glycero-D-talo-heptitol and -D-galactoheptitol

D-glycero-D-talo-Heptose and D-glycero-Dgalacto-Heptose

1-Deoxy-1-nitro-D-glycero-L-manno-heptitol and -L-glucoheptitol 2-0-Benzyl-D-galactose 3-0-Benzyl-1-deoxy-1-nitro-D-glycero-L-manno-heptitol 4,6-0-Benzylidene-D-glucopyranose 5,7-O-Benzylidene-l-deoxy-l-nitro-~-glycero-~-gulo-heptitol 2-Acetamido-2-deoxy-3,4:5,6-di-O-isopropylidene-~3-Acetamido-l,3-dideoxy-4,5:6,7-di-O-isopropylidene-l-nitroglucose D-glycero-D-ido-heptitol D-Galactose

Methyl 2,3-di-0-acetyl-4-deoxy-0-L-tkreo-hex-4- Methyl 2,3-di-O-acetyl-4,7-dideoxy-7-nitro-~-(and -L-) enodialdo-1,5-piranoside glycero-P-L-threo-hept-4-enopyranoside D-Idose 1-Deoxy-1-nitro-D-glycero-L-gulo-heptitol and -L-ido-heptitol

1-Deoxy-1-nitro-D-arabino-L-galacto-nonitol and -L-talononitol

D-erythro-L-mannoOctose D-arabino-L-galactoNonose

48


namically more stable epimer is predominant. Besides these compounds zyclization of the open-chain 1-deoxy-l-nitroalditols into 2,5-anhydrides was also observed. Similar to the nitroalditols, three maxima appear in the CD spectra of the anhydro derivatives, but the bands intensities are usually significantly larger for the former substances. A shoulder is observed at 310 nm, the n ~ 7r* transition is at -~275 nm, and the more intense band appears at 210 nm. 56 Detailed studies 66 have shown that related dehydration of C-2 epimeric 1-deoxy-l-nitroalditols gives rise to a single anhydro derivative, and this is the derivative in which the nitromethyl group is equatorially oriented. In such cases the steric arrangement of the C-1 and C-2 substituents is conformationally the most favored, as in the example given in Figure 1.28, showing the transformation 66 of the mannitol (28.1) and glucitol (28.3) into the same compound: 2,6-anhydro-l-deoxy-l-nitro-D-mannitol (28.2). Preparation of 2,6-anhydro-l-deoxy-l-nitro-o-mannitol (28.2) 66 A solution of 20 g of 1-deoxy-l-nitro-D-mannitol (28.1) (or glucitol, 28.3) in water (200 ml) is boiled until the specific optical rotation value is constant (--~2 days). Concentration of the solution results in the crystallization of the product (28.2) (11.5 g, 63%), m.p. 170-171~ [a]~ -52.5 (c = 4 in water).

Dehydration of the 1-deoxy-l-nitroalditols 29.1 and 29.2, derived from D-ribose, is not as simple as in the preceding case, since separation of the products (29.3 and 29.4) requires column chromatographic technique (Fig. 1.29). 2,5-Anhydro-l-deoxy-l-nitro-o-altritol (29.3) and 2,5-anhydro-l-deoxy-l-nitroo-allitol (29,4) 37'66 A mixture of D-ribose (15 g, 0.1 mol) in methanol (100 ml) and nitromethane (6 ml, 0.11 mol) and potassium carbonate (13.8 g, 0.1 mol) is stirred until all the starting sugar has reacted (---6 h; thin-layer chromatography (TLC: 1:3 CC14-acetone). After dilution with water, the mixture is deionized with Amberlite IR-120 (H § resin which is then filtered off; then the filtrate concentrated and the residue is codistilled several times with ethanol to give 3.28 g (17%) of 2,5anhydro-l-deoxy-l-nitro-D-altritol (29.3), which can be recrystallized from 2-propanol to afford 1.39 g (10%) of the pure product, m.p. 139-140~ [a]2o2 +79 (c = 1 in water). The residue obtained on evaporation of the mother liquor is

HO

CH2NO2 '

HO

CH2NO2 OH t~

OH OH

>

O ~O H- H ~0 H CH2NO2 OH

CH2OH 28.1

HO

29.2

OH

H2NO 2

cH2NO2

+ HO

29.3

OH

29.4

FIGURE 1.29

subjected to column chromatography (eluant: ethyl acetate) to yield 12 g (62%) of 2,5-anhydro-l-deoxy-l-nitro-D-allitol, [a]~ - 7 (c = 1.5 in water). T h e c o r r e s p o n d i n g pair o f p y r a n o s y l d e r i v a t i v e s is p r e p a r e d a c c o r d i n g to a m e t h o d 37,66 that u s e s D M S O as t h e s o l v e n t . T h e s y n t h e s i s o f 2,6-

anhydro-l-deoxy-l-nitro-D-glycero-D-manno-heptitol p e r f o r m e d 56 in D M S O

( 3 0 . 2 ) has a l s o b e e n

(Fig. 1.30).

2,6-Anhydro-l-deoxy-l-nitro-D-glycero-D-manno-heptitol (30.2)from D-galactose (30.1) 56 To a solution of D-galactose (30.1) (50 g) in DMSO (200 ml) a mixture of nitromethane (100 ml) and sodium methoxide solution (prepared from 12.5 g of sodium and 350 ml of dry methanol) is added and stirred for i day. The precipitate separating on addition of n-butanol (100 ml) is filtered off, washed with cold methanol (2 x 50 ml), and added to a mixture of water (100 ml), cation-exchange resin (H+; 150 g), and dry ice (50 g). The resin is filtered off and washed with water (3 • 100 ml), and the fitrate-washing combination is passed through a 30 • 2 cm column filled with cation-exchange resin. The eluate is concentrated to ---50 ml, heated at 100~ for 30 h, decolorized with charcoal, filtered, and mixed with 151 g of Dowex 1 x 4 (297 • 149/xm) anion-exchange resin. After remaining for 1 h with occasional rinsing, the resin is filtered off and washed with water (1 liter). The washed resin is stirred with 100 ml of water and warmed to 20~ and 100 g of dry ice is added to cool down (but not freeze) the mixture. The resin is filtered off and washed with water (3 • 100 ml), and the combined aqueous solution is concentrated to obtain 41 g (66%) of crude 30.2, which is then recrystallized from methanol. The pure product has m.p. 198-200~ and [a]2D~ +37 (C = 2 in water). Workup of the mother liquor gives three additional stereoisomers, as minor products. T h e c h a i n e x t e n s i o n o f a l d e h y d e s w i t h n i t r o m e t h a n e c a n a l s o b e catal y z e d w i t h p o t a s s i u m f l u o r i d e 67 a n d c r o w n e t h e r s . If t h e t a r g e t c o m p o u n d

F--OH .# O ~OH I~OH

HO

OH

30.1

CH3NO2 OMe-

>

CH2NO2 OH --OH HO-HO--

CH2NO2 HO OH HO HO

..

--OH

OH

CH2OH

CH2OH

FIGURE 1.30

t~

HO H

OH OH 30.2

CH2NO2

50


CH2NO2

H~c~O

O CH 3 ~oXcH3 Me I tBu--SiI O Me L--OTr

I,CH3NO 2 2,Ac20 3,NaBH4

31.1

>

Me

~---[O CH 3 CH2~_oXcH 3

I tBu--Si-O I Me L--OTr 31.2

F I G U R E 1.31

is t h e C-2 d e o x y derivative, t h e e p i m e r i c 1 - d e o x y - l - n i t r o a l d i t o l s are Oa c e t y l a t e d a n d t h e n r e d u c e d into t h e r e q u i r e d n i t r o a l k a n e . In t h e field of c a r b o h y d r a t e s , t h e c o n v e r s i o n of a l d e h y d e s into s a t u r a t e d n i t r o c o m p o u n d s was e x e c u t e d w i t h p r o t e c t e d aldehydo-sugars, a n d this m e t h o d o l o g y has b e e n u s e d m o s t successfully 68 for c h a i n e x t e n s i o n , as s h o w n in F i g u r e 1.31.

5-O-(tert-B uty ldimethylsily l)-l,2-dideoxy-3,4-O-is op rop y lidene-l-nitro-6-Otriphenylmethyl-L-arabino-hexitol (31.2) 68 To a solution of the aldehydo-L-arabinose derivative 31.1 [freshly prepared from 4-O-(tert-butyldimethylsilyl)-2,3O-isopropylidene-5-O-triphenylmethyl-L-arabinose diethyl dithioacetal (5 g, 7.7 mmol)] in dry 2-propanol (25 ml) nitromethane (2 ml, 37 mmol), anhydrous potassium fluoride (50 mg, 0.86 mmol) and 18-crown-6 (120 mg, 0.45 mmol) are added and the mixture is stirred at room temperature. The progress of the reaction is monitored by TLC (10:1 benzene-ether). The solvent is distilled off, the foamy residue is dissolved in dry ether (30 ml), and acetic anhydride (2 ml) and 4-dimethylaminopyridine (60 mg, 0.5 mmol) are added. After 50 min TLC (97:3 benzeneether) shows the presence of two more polar products. Ether is distilled off, 100 ml of dry ethanol is added, the mixture is cooled down on an ice bath and 2.2 g (58 mmol) of sodium borohydride is cautiously added. TLC (benzene) shows the formation of a new product (whose spot is situated inbetween the spots of the former two compounds), After completion of the reaction the solvent is distilled off, hexane (100 ml) and water (50 ml) are added, and the mixture is cooled down on an ice bath and acidified with 10% aqueous aceteic acid. The aqueous layer is separated, and washed with hexane (2 • 100 ml), the combined organic layer is washed with water (3 • 100 ml), washed with saturated aqueous sodium hydrogencarbonate solution until neutral, washed again with water, and dried over MgSO4. The thick syrup obtained on evaporation is subjected to column chromatography (eluant: 8:100 ethyl acetate-hexane) to afford 3.8 g (83% calculated to the starting dithioacetal) of pure 31.2, [c~]2D 2 --1.1 (C = 10 in chloroform).

1.2.3.2. Chain Extension with Nitroethane E x t e n s i o n of t h e c a r b o n chain w i t h t w o c a r b o n a t o m s n e c e s s i t a t e s t h e a p p l i c a t i o n of n i t r o e t h a n e . D e s p i t e t h e a v a i l a b l e m o d e r n t e c h n i q u e s , t h e s e p a r a t i o n a n d s t r u c t u r e e l u c i d a t i o n of t h e f o u r t h e o r e t i c a l l y possible isom e r s p r o d u c e d in such r e a c t i o n s are s o m e t i m e s r a t h e r tedious. C o n d e n s a t i o n of 1,2:3,4-di-O-isopropylidene-a-D-galacto-hexodialdo1 , 5 - p y r a n o s e (32.1) with n i t r o e t h a n e (Fig. 1.32) r e s u l t e d in t h r e e i s o m e r i c 7 , 8 - d i d e o x y - 7 - n i t r o a l d i t o l s (32.2) t h a t c o u l d be i s o l a t e d in t h e f o r m of

1.2. BUILDUPOF SUGARSWITH ASCENDING SYNTHESIS

5 I

OH3 CliO 0

HaG

CH3CH2NO2

CH3

O

,O

o5

OH3 CHa 32.1

32.2

F I G U R E 1.32

the corresponding acetates. 69 A similar mixture of isomers (Fig. 1.33), consisting of 6,7-dideoxy-l,2-O-isopropylidene-3-O-methyl-6-nitro-D,Lglycero-D-gluco and L-ido-heptofuranose (33.2), is produced 7~ from 1,2-Oisopropylidene-3-O-methyl-c~-o-xylo-pentodialdo-l,4-furanose (33.1) on condensation with nitroethane. In the reaction shown in Figure 1.34, a nonseparable mixture of the isomeric (tert-butyldimethylsilyl)-6,7-dideoxy. 2,3-O-isopropylidene-6-nitroheptofuranosides (34.2) was obtained 71 in 60% overall yield from the dialdose (34.1). In the case of D-mannose (35.1), the formation of only two isomers is observed 72 (Fig. 1.35) and treatment of the unseparated, crystalline mixture of 1,2-dideoxy-2-nitrooctitols (35.2) with dilute sulfuric acid gives rise to a single product: 1-deoxy-o-glyceroD-galacto-octulose (35.3). 1-Deoxy-o-glycero-o-galacto-octulose (35.3) A cold solution of sodium hydroxide (18 g, 0.45 mol) in water (20 ml) is mixed with 125 ml of methanol, and this solution is added to a suspension of D-mannose (35.1, 40 g, 0.22 mol) in methanol (175 ml) and nitroethane (100 ml). From the resulting clear solution, precipitation of the nitronate salt begins in --~1 h, and this is complete in a week to obtain, after filtration, 60 g of the crude product, m.p. 135-140~ A solution of the crude nitronate (30 g, 0.11 mol) in water (100 ml) is added dropwise to a soluiton of sulfuric acid (13.4 ml, 0.25 mol) in water (10 ml). When the gas evolution is complete, the solution is consecutively passed through a column of 600-ml of a Bio Rad A G

CH3 FNO

HC~"Oo

~a3~,

~

H3C

CHOH

ca3ca2ao2 0

~OCO

>

OH3

H

o,f i\

H3C

33.1

33.2

F I G U R E 1.33

OH3

52

I ASCENDING SYNTHESIS OF MONOSACCHARIDES OH3

FF-oH

CliO

NO

~O~O~

CH3CH2NO2

Me

~]_" "~/;__ sli__Bu_t I Me

o~oo Me I

--Si-Bu-t I

Me 34.1

34.2

FIGURE 1.34

3-X4 (OH-) anion-exchange column, and then a 600-ml Dowex 50 (H +) cationexchange column and the deionized solution is neutralized with a small amount of Dowex 1 (HCO?) and concentrated to a syrup. Crystallization from ethanol gives 13.6 g (55% calculated for I)-mannose) of 35.3, m.p. 149-151~ [oz]~ +87 (in water, end value). By means of the fractional crystallization of the acidified aci-nitro salt mixture, the two epimeric 1,2-dideoxynitrooctitols can be isolated. In agreement with the previous work, nitroethane condensation of Dgalactose gave two products in a 3 : 2 ratio, which could be isolated (in 24% yield) as a crystalline substance and then separated 73 in the form of crystalline acetyl derivatives. 1.2.3.3. Chain Extension with Nitroethanol

W h e n aldoses are submitted to a condensation reaction with nitroethanol under the conditions described in the previous sections, ketoses extended by two carbon atoms in the chain are obtained. So far this m e t h o d has been attempted only with the four D-series pentoses, and the ketoses were obtained 74 with moderate yields (Table 1.9) even when the isomeric 2-deoxy-2-nitroheptitols were not separated. The reaction of 1,2-dideoxy-3,4-O-isopropylidene-l-nitro-L-glycerotetritol (36.1) with O-benzyl-L-lactaldehyde (36.2) gave (Fig, 1.36) three isomeric heptitols (36.3), and on catalytic hydrogenation and subsequent

r O.o

H

4 OH HO~ z ~ OH + CH3CH2NO2

OH -

HO > HO

CH3 ~NO 2 OH

OH 3

HO > HO

HO HO ~ " ' ~ OH

H2SO4

OH OH CH2OH 35.1

0 OH

35.2

FIGURE 1.35

", OH OH CH2OH 35.3

HOOCH3 OH

-'7.2. BUILDUP OF SUGARS W I T H ASCENDING SYNTHESIS

T A B L E 1.9

Nitroethanol Condensations Carried O u t with

,,~3

P e n t o s e s 74

Pentose

Product

Yields (%)

D-Arabinose

D-gluco-Heptulose D-manno-Heptulose

11 4

D-Xyl0se D-Ribose D-Lyxose

2,7-Anhydro-fl-D-ido-heptulopyranose 2,7-Anhydro-fl-D-altro-heptulopyranose D-galacto-Heptulose D-talo-Heptulose

18.9 4.8 7.7 1.7

acetylation, three aminodeoxyheptitols (36.4) could be isolated, each with --~15% yield. 75 The nitroaldol condensation of 2-O-benzyl-D-glyceraldehyde (37.1) with the nitroacetal 37.2 in the presence of tetrabutylammonium fluoride catalyst (Fig. 1.37) allowed the preparation 76 of 2-amino-2-deoxypentoses (arabino: ribo ratio 88: 12). 1.2.3.4. Chain Extension with Nitroalkane Carboxylic Acids

In the presence of ammonium acetate catalyst, 2,3 : 4,5-di-O-isopropyli-

dene-aldehydo-D-arabinose (38.1) undergoes condensation (Fig. 1.38) with ethyl nitroacetate (38.2) to afford 77 a mixture of 2-deoxy-3-hydroxy-4,5 : 6,7di-O-isopropylidene-2-nitro-L-arabino-heptonic acids (38.3), whereas a double addition occurs in the presence of other amines. Methyl nitroacetate (39.2) was used for the chain extension (Fig. 1.39) of 5-deoxy-D-xylose (39.1), which resulted in a single isomer. According to spectroscopic studies, 37 this compound must be methyl 3,6-anhydro-2,7dideoxy-2-nitro-D-glycero-L-talo- (or L-galacto)-heptonate (39.3). Methyl nitropropionate is applied when extension of the carbon chain by three carbon atoms is required. With this ester (40.2), 2,3-di-O-benzyl4,5-O-isopropylidene-aldehydo-L-arabinose (40.1) gives a mixture of diastereoisomeric octonic acids (40.3) in the presence of diisopropylamine catalyst as shown in Figure 1.40.

,c•

H3C_

H3C _

O

H~cXo

cH~

,c•

O--1

~ BnO

_~oH zAc2o

H3C_

>

O"--'1

[*,-oAc

BnO--- 1

OH3 36.1

36.2

36.3

F I G U R E 1.36

OH3 36.4

54


H~'c~'O H+OBn CH2OH

HC(OC2H5)2 L NO2

+

[

HC(OC2H5)2 w~NO2

(nBu)4N+ F-

~O:n CH2OH

37.1

37.2

37.3

F I G U R E 1.37

CO2C2H5 NO

H~.c~O ~ C H 3 0:~ "CH3

H c•

NO2CH2CO2C2H5

FF,,,o.

NH4OAc

N3C

H3C-

~__.~CH3 O===1"OH3 O~-~

H~cXo/ 38.1

38.2

38.3

F I G U R E 1.38

H3C

O +

NO2CH2CO2CH3

OH 39.1

OH 39.3

39.2

F I G U R E 1.39

(~O2CH3 CH2 'w~NO2

H ~ c~,O

BnO@ OBn

NO2CH2CH2CO2CH3

(iPr)2NH DMF

,~,,OH

BnO H3C O-H3cXo -

40.1

40.2

F I G U R E 1.40

40.3

--OBn


55

CO2CH3 I

OH2

H-,.c~.O ~~._CH O'~: T H3CxO ~

3

"OH 3

+

NO2CH2CH2CO2CH 3

KOtBu THF

H3C

J~NO2

~,,~OH

> H3C_

~ ~ - - ' ~ OH3 O ===::[ "OH3 0 - - - 4

H3CXO -J 41.1

41.2

FIGURE 1.41

2,3:4,5-Di-O-isopropylidene-aldehydo-L-arabinose (41.1) can be readily condensed, as well, (Fig. 1.41) with methyl nitropropionate to a mixture of dideoxyoctonic acids (41.2). This reaction is complete in less than 30 min when potassium tert-butoxide is applied as the catalyst. 78 Condensation of C3-aldehydes with methyl nitropropionate is a very important tool for the total synthesis of naturally occurring aminodeoxy hexoses, the sugar components of various antibiotics. 79 Protected lactaldehydes, such as (2S)-[tetrahydro-2H-pyran-2(R,S)-yl-oxy]propanal 8~ (42.1) (see Fig. 1.42) or (2S)-benzyloxypropana181 have been transformed into methyl 2,3,6-trideoxy-3-nitrohexonates, subjects for further conversion into the rare 3-amino-2,3,6-trideoxy-L-hexose building units of antibiotics. The reaction of 42.1 with methyl nitropropionate (Fig. 1.42) gives a mixture of methyl 2,3,6-trideoxy-3-nitro-L-hexonates (42.2)in a non~O2CH3

( y_o+ O

CHO

,

OH3

+

NO2CH2CH2CO2CH3

.....

.>

OH2 ,,"NO2

§

0

0

H3CX CH3

51.1

51.2 FIGURE

65

0

H3c X

0

OH3

51.3

1.51

0.2 mmol) are added, and the mixture is stirred at room temperature for 140 min. It is then concentrated under diminished pressure; the residue is taken up with water, extracted with ether, the organic layer is evaporated, and the residue (1 g) is submitted to column chromatography on a silicagel column (60 g) with 1:2 ethyl acetate-hexane as the eluant. The first fraction contains the pure B-isomer 51.3 (18 mg, 2%), [a]D +3.0 (C = 1.4 in chloroform), followed by an anomeric mixture (105 mg, 11%), and the last fraction consists of the pure oz anomer 51.2 (730 mg, 74%), as an amorphous powder, [O~]D --25.5 (C = 1.1 in chloroform).

Condensation of 1-deoxy-2,3"5,6-di-O-isopropylidene-l-nitro-c~-Dmannofuranose (52.1) with the dialdose derivative 52.2 (Fig. 1.52) furnished the dodeculose 52.3 in a diastereoselective reaction, and the structure of the product could be unequivocally proved by X-ray measurements. 7-Deoxy-l,2 : 3,4: 8,9: ll,12-tetra-O-isopropylidene- 7-nitro-B-D-manno-D-glycero-a-D-galacto-dodeco-l,5-pyranos-7-ulo-7,10-furanose (52.3) 97 To a mixture of the deoxynitrofuranose 52.1 (289 mg, 1 mmol) and 1,2:3,4-di-O-isopropylidene-a-D-galacto-hexopyranos-l,5-ulose (52.2, 516 mg, 1 mmol) in dichloromethane (5 ml) tetrabutylammonium fluoride is added in three portions (114, 74, and 30 mg, 0.69 mmol) at 20-min intervals at room temperature. The mixture is stirred for a further 45 min, and concentrated, and the yellow, syrupy residue is submitted to column chromatography (eluant: 1:3 ethyl acetate-hexanes). The first fraction contains the unreacted ulose 52.2 (196 mg, 0.76 mmol), followed by a mixture (64 mg) of two nonidentified by-products. The third fraction (496 mg, 90%) contains the crude title product 52.3, which is recrystallized from ether-hexanes to afford the pure sugar (427 mg, 78%), m.p. 172.5-173~ [a]~ -15.2 (c = 1.0in chloroform).

On solvolysis, or treatment with sodium hydrogencarbonate in N,Ndimethylformamide, the deoxynitro disaccharide 52.3 can be readily transformed (Fig. 1.52) into 1,2:3,4:8,9:11,12-tetra-O-isopropylidene-D-mannoD-glycero-a-D-galacto-dodeco-l,5-pyranos-7-ulo-7,10-furanose 97 (52.4), orm after O-acetylationmthe resulting sugar is reduced with tri-n-butyl stannane into 6-acetoxy-7,10-anhydro-l,2:3,4 : 8,9:11,12-tetra-O-isopropylidene-aD-erythro-L-manno-D-galacto-dodeco-l,5-pyranose (52.5), which is produced from an intermediary radical as the more stable product. 98 The transformation shown in Figure 1.53 is also based on the previous principle, allowing a straightforward route 99 to N-acetylneuraminic acid by means of the nitroaldol condensation of the 1-deoxy-l-nitro-D-glucosamine (53.1) derivative with 1,2-O-cyclohexylidene-D-glyceraldehyde (53.2) to give the chain-extended nonitol 53.3.

66

I ASCENDINGSYNTHESISOF MONOSACCHARIDES CHO "c.O H~cXo__I

o

~o~.o~

NO2

52.1

§

o

H~C

I

CH3 CH3 52.2

Bu4N+F-

H3C. O-'--I H3CXOJo

NO2 \H OH O

O O

H3CCH3

~~CH 3 CH3

.,:~"

~ 0 0 3

H3C_ 0---7 H3cXo__I

52.3

GH 3

O

9@CH~

OH

,

H3C--~O

1, AC20

OH

2, nBu3SnH ~" H~C"7 N CH3

H6~OO~O

53.1

O

~"~H

FIGURE 1.52

H...c~/O

Ac

l~O~J~'O;

H3C .O--7 I H3cXoq /O.]

,10 /~CH3 CH3

52.4

O/

(CH3]4N+OH-

53.2

52.5

H

O

53.3

FIGURE 1.53

-

67

1.2. BUILDUP OF SUGARS WITH ASCENDING SYNTHESIS ( 4 R ) - 5 - A c e t a m i d o - 4,8- anh y dro - 7,9- O - b en z y lidene - l ,2 - O- cy clo h e x y lidene - 5-

deoxy-4-nitro-o-gluco-L-erythro-nonitol (53.3) 99 To a solution of the 1-deoxy-1-

nitro-D-glucosamine derivative (53.1, 4.0 g, 11.8 mmol) in N,N-dimethylformamide (30 ml) a mixture of tetramethylammonium hydroxide in methanol (0.3 ml, 1.5 mol) and 2,3-O-cyclohexylidene-o-glyceraldehyde (53.2, 1.5 g, 8,8 mmol) is added, and the same amount of these reagents added, again, three times at 45 min intervals. The reaction mixture is stirred for an additional hour, and the solvents are removed under reduced pressure. The residue is purified by means of column chromatography on 500 g of silicagel (eluant: 1:1 ethyl acetate-hexanes) to afford pure 53.3 as a foam, [o~]~ + 17.4 (c = 1.1 in chloroform). The product can be converted into the crystalline diacetate (m.p. 148-149~ [o~]~ -3.8 (c = 1.1 in chloroform) by treatment with acetic anhydride in pyridine.

1.2.3.7. Nitroaldol Condensation with C-GlycopyranosylNitromethane Derivatives 2,6-Anhydro-l-deoxy-l-nitroheptitols ("C-glycopyranosyl-nitromethanes"), which can be formally r e g a r d e d 1~176 as C-glycosidic c o m p o u n d s , are also excellent educts for chain extension with the nitroaldol c o n d e n s a t i o n m e t h o d o l o g y . Such t r a n s f o r m a t i o n s h a v e b e e n effected 56,65,1~176 with the available 2 - a c e t a m i d o - 2 - d e o x y - 2 , 6 - a n h y d r o - l - d e o x y - l - n i t r o h e p t i t o l s possessing D - g l u c o - , o - a l l o - , D - a l t r o - , D - g a l a c t o - and o - m a n n o configurations. W h e n a solution of 2 , 6 - a n h y d r o - 7 - d e o x y - 7 - n i t r o - L - g l y c e r o - L - g a l a c t o heptitol (54.1, " C - g a l a c t o p y r a n o s y l - l f i t r o m e t h a n e " ) in Me2SO is t r e a t e d 1~ with f o r m a l d e h y d e in the p r e s e n c e of s o d i u m m e t h o x i d e (Fig. 1.54), a mixture of 3 , 7 - a n h y d r o - 2 - d e o x y - 2 - n i t r o - D - t h r e o - L - g a l a c t o - o c t i t o l (54.2) and the c o r r e s p o n d i n g e r y t h r o - i s o m e r (54.3) is p r o d u c e d , and an analogous IOH +

CH20

NaOCH3 > DMSO

HO

O C--NO2- Na+ OH

ON 54.1

NaOCH~ I cHoCH~OH

H?/

F-OH O\

OH L

I

OH

H~)~ O2N~ OH

.o

;N:2

OH OH

54.4

54.2

OH

54.3

+ 2 products 3,7-anhydro-2-deoxy-2-nitroD- threo-L-galacto-octitol

F I G U R E 1.54

3,7-anhydro-2-deoxy-2-nitroL-erythro-L 'galacto-octitol

O-

OAc i~? Ac 2 AcO "a /t OAc

base

+ t-BuMe2SiCl

OSiMe2tBu

IO•AcOAc/

AcO "J

I

OAc 55.2

55.1

Base

Solvent

Yields (%)

Et3N

C6H5-CH2CI2

30

LDA

THF

53

Nail

THF

59

DBU

CH2C!2

95

F I G U R E 1.55

r--OAc NO2 /.[------O\ / , ~ . ~ O H

CHO

~ - - o r-"~"

~ ~ r - ~ oO

~ I--- OAc \ J

~'N?Ac 2 AcO ~ O A c

H3C

CH3

56.1

~ ,~ Aco~'~?Ac ~ OAc /

o,~\

~.O H3C"- / CH3

O--'~CH3 OH3

o/~O \

0 - ' ~ OH3 OH3

56.2

I Ac20

OAc

[---OAc

NO2 * - - - -

OAc

O OH3

~o~c y

AcO

OAc

F

/O-~o~

/OH3

.o. H3C OH3

O----~ CH3 CH3

l n,Bu3SnH

F-OA~ AcO ~

1, NaOMe

r~ ) - - - - - - 0 -

2, H+ OH3

HO~

OH

HO )-----0 ~~,~OH

O--~CH 3 C.H~

F I G U R E 1.56

OH 56.3


69

reaction of the g l u c o p y r a n o s e analog has also b e e n r e p o r t e d . TM With the addition of glycolaldehyde, the f o r m a t i o n of four isomeric n i t r o n o n i t o l s was expected; t h r e e of these w e r e o b s e r v e d w h e n the sugar 54.1 was s u b m i t t e d to nitroaldol c o n d e n s a t i o n . X - R a y m e a s u r e m e n t s on t h e single crystalline p r o d u c t isolated s h o w e d 1~ the structure of this c h a i n - e x t e n d e d sugar to be 4 , 8 - a n h y d r o - 3 - d e o x y - 3 - n i t r o - D - l y x o - o - g l u c o - n o n i t o l (54.4). M a r t i n et a1.1~176 have applied the " s i l y l n i t r o n a t e " c h a i n - e l o n g a t i o n p r o c e d u r e also for the family of sugars discussed earlier. Figure 1.55 shows the results of a r e l a t e d t r a n s f o r m a t i o n of the g l u c o - s u g a r 55.1 into the n i t r o n a t e 55.2 in the p r e s e n c e of various bases and solvents. Silylnitronates readily react with a r o m a t i c aldehydes, but an analogous nitroaldol c o n d e n s a t i o n with a l d e h y d o - s u g a r s p r o c e e d s m o r e advantageously in the p r e s e n c e of p o t a s s i u m fluoride and 18-crown-6. Such an example, w h e n b o t h r e a c t i o n p a r t n e r s are sugar derivatives, is shown in Figure 1.56. By applying the n i t r o m e t h y l glucose 56.1 and the galactodialdose 56.2, and following c o n v e n t i o n a l synthetic t r a n s f o r m a t i o n s , 8,12a n h y d r o - 6 , 7 - d i d e o x y - D - g l y c e r o - o - g u l o - o - g a l a c t o - t r i d e c o s e (56.3), the carb a s u g a r a n a l o g of the disaccharide/3-D-Glcp-(1 ~ 6)-D-Galp could be synthesized.

REFERENCES T O S E C T I O N 1.2.3 1. Houben-Weyl, Methoden der Organischen Chemie, Vol. X/1. p. 251 (1971). 2. J. C. Sowden, Adv. Carbohydr. Chem. 6, 291 (1951); J. M. Webber, ibid. 17, 15 (1962); H. H. Baer, Adv. Carbohydr. Chem. Biochem. 24, 64 (1969). 3. P. K611, C. Stenns, W. Seelhorst, and H. Brandenburg, Justus Liebigs Ann. Chem., p. 201 (1991). 4. P. K611, H. Brandenburg, W. Seelhorst, C. Stenns, and H. Kogelberg, Justus Liebigs Ann. Chem., p. 207 (1991). 5. D. E. Koshland, Jr. and F. H. Westheimer, J. Am. Chem. Soc. 71, 1139 (1949); 72, 3383 (1950). 6. J. C. Sowden, Science 109, 229 (1949); J. Biol Chem. 180, 55 (1949). 7. J. C. Sowden and H. O. L. Fischer, J. Am. Chem. Soc. 69, 1048 (1947). 8. C. Satoh and A. Kiyomoto, Carbohydr. Res. 3, 248 (1966); C. Satoh, A. Kiyomoto, and T. Okuda, Carbohydr. Res. 5, 140 (1967). 9. J. Stanek, M. Cerny, J. Kocourek, and J. Pacfik, The Monosaccharides, p. 148, Publ. House Czech. Acad. Scie., Prague, 1963; A. C. Richardson in Int. Rev. Sci.: Org. Chem., Ser. Two 7, 136 (1976). 10. B. O. Gusev, T. Mitrofanova, O. N. Tolkachev, and R. P. Evstigneeva, Khirn. Prir. Soedin., p. 8 (1972). 11. J. M. J. Tronchet, K. D. Pallie, and F. Barbalat-Rey, J. Carbohydr. Chem. 4, 29 (1985). 12. J. C. Sowden, Methods Carbohydr. Chem. 1, 132 (1962). 13. J. C. Sowden and D. R. Strobach, J. Am. Chem. Soc. 82, 954 (1960). 14. L. Hough and S. H. Shute, J. Chem. Soc., p. 4633 (1962). 15. H. P. Albrecht, D. P. Repke, and J. G. Moffatt, J. Org. Chem. 38, 1836 (1973). 16. D. B. Repke, H. P. Albrecht, and J. G. Moffatt, J. Org. Chem. 40, 2481 (1975). 17. V. Bflik, Collect. Czech. Chem. Commun. 39, 1621 (1974).

70

I


18. J. C. Sowden, Methods Carbohydr. Chem. 1, 132 (1962). 19. A. P. Kozikowski, Y. Kitagawa, and J. P. Springer, J. Chem. Soc., Chem. Commun., p. 1460 (1983). 20. J. C. Sowden and R. R. Thompson, J. Am. Chem. Soc. 80, 2236 (1958). 21. J. C. Sowden, J. Am. Chem. Soc. 72, 808 (1950). 22. D. H. Murray and G. C. Butler, Can. J. Chem. 37, 1776 (1959). 23. D. A. Rappoport and W. Z. Hassid, J. Am. Chem. Soc. 73, 5524 (1951). 24. K. D. Carlson, C. R. Smith, Jr., and I. A. Wolff, Carbhydr. Res. 13, 391 (1970). 25. J. C. Sowden, U.S. Patent 2,530,342 (1950); Chem. Abstr. 45, 2971 (1951). 26. C. Satoh and A. Kiyomoto, Chem. Pharm. Bull 12, 615 (1964). 27. J. C. Sowden and H. O. L. Fischer, J. Am. Chem. Soc. 69, 1963 (1947). 28. H. Paulsen and W. Grewe, Chem. Ber. 106, 2114 (1973). 29. J. C. Sowden and H. O. L. Fischer, J. Am. Chem. Soc. 66, 1312 (1944). 30. J. C. Sowden and H. O. L. Fischer, J. Am. Chem. Soc. 67, 1733 (1945). 31. J. Yoshimura and H. Ando, Nippon Kagaku Zasshi 85, 138 (1964); Chem. Abstr. 61, 16140d (1964). 32. J. C. Sowden and H. O. L. Fischer, J. Am. Chem. Soc. 69, 1048 (1947). 33. W. W. Zorbach and A. Ollapally, J. Org. Chem. 29, 1790 (1964). 34. R. N. Ray, J. Indian Chem. Soc. 65, 880 (1988). 35. T. Takamoto, H. Omi, T. Matsuzaki, and R. Sudoh, Carbohydr. Res. 60, 97 (1978). 36. M. B. Perry and V. Daoust, Can. J. Chem. gl, 3039 (1973). 37. T. Sakakibara, T. Takamoto, T. Matsuzaki, H. Omi, U. Win Maung, and R. Sudoh, Carbohydr. Res. 95, 291 (1981). 38. H. Paulsen, Justus Liebigs Ann. Chem. 665, 166 (1963). 39. J. M. Grosheintz and H. O. L. Fischer, J. Am. Chem. Soc. 70, 1476 (1948). 40. J. M. Grosheintz and H. O. L. Fischer, J. Am. Chem. Soc. 70, 1479 (1948). 41. R. L. Whistler and R. E. Pyler, Carbohydr. Res. 12, 201 (1970). 42. J. M. J. Tronchet, K. D. Pallie, J. Graf-Poncet, J. F. Tronchet, G. H. Werner and A. Zerial, Eur. J. Med. Chem.~Chim. Ther. 21, 111 (1986). 43. J. Kov~ir and H. H. Baer, Can. J. Chem. 51, 1801 (1973). 44. J. M. J. Tronchet, K. D. Pallie, and F. Barbalat-Rey, J. Carbohydr. Chem. 4, 29 (1985). 45. T. Iida, M. Funabashi, and J. Yoshimura, Bull Chem. Soc. Jpn. 46, 3203 (1973). 46. M. Funabashi, K. Kobayashi, and J. Yoshimura, J. Org. Chem. 44, 1619 (1979). 47. M. Iwakawa, J. Yoshimura, and M. Funabashi, Bull Chem. Soc. Jpn. 54, 496 (1981). 48. S. Ogawa, K. L. Rinehart, Jr., G. Kimura, and R. P. Johnson, J. Org. Chem. 39, 812 (1974). 49. J. M. J. Tronchet, S. Zerelli, N. Dolatshaki, and H. Ttirler, Chem. Pharm. Bull 36, 3722 (1988). 50. A. R. Moorman, T. Martin, and R. T. Borchardt, Carbohydr. Res. 113, 233 (1983). 51. R. K. Hulyalkar, J. K. N. Jones, and M. B. Perry, Can. J. Chem. 41, 1490 (1963). 52. D. T. Williams and M. B. Perry, Can. J. Chem. 41, 1490 (1963). 53. J. C. Sowden and R. Schaffer, J. Am. Chem. Soc. 73, 4662 (1951). 54. V. Bflik, J. AlfOldi, and K. Bl'likov~i, Czech. Pat. CS 263,174 (1989); Chem. Abstr. l l 3 , 244212g (1990). 55. O. P. Singh and G. A. Adams, Carbohydr. Res. 12, 261 (1970). 56. L. Petru~, S. Bystricky, T. Sticzay, and V. Bflik, Chem. Zvesti 36, 103 (1982). 57. J. C. Sowden and H. O. L. Fischer, J. Am. Chem. Soc. 68, 1511 (1946). 58. L. Benzing and M. B. Perry, Can. J. Chem. 56, 691 (1978). 59. J. Yoshimura, H. Sakai, N. Oda, and H. Hashimoto, Bull Chem. Soc. Jpn. 45, 2027 (1972). 60. D. Horton and A. Liav, Carbohydr. Res. 24, 105 (1972). 61. J. Kowir and H. H. Baer, Can. J. Chem. 48, 2377 (1970). 62. J. V. Karabinos and C. S. Hudson, J. Am. Chem. Soc. 75, 4324 (1953). 63. J. C. Sowden and D.R. Strobach, J. Am. Chem. Soc. 82, 956 (1960).

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71

64. M. Teuber, R. D. Bevill, and M. J. Osborn, Biochemistry 7, 3303 (1968). 65. J. C. Sowden and M. L. Oftedahl, J. Org. Chem. 26,1974 (1974); A. FOrtsch, H. Kogelberg, and P. K011, Carbohydr. Res. 164, 391 (1987). 66. P. K611, J. Kopf, D. Wess, and H. Brandenburg, Justus Liebigs Ann. Chem., p. 685 (1988). 67. R. H. Wollenberg and S. J. Miller, Tetrahedron Lett. 19, 3219 (1978). 68. G. Just and D. R. Payette, Tetrahedron Lett. 21, 3219 (1980); D. R. Payette, and G. Just, Can. J. Chem. 59, 269 (1981); G. Just and H. Oh, ibid., p. 2729. 69. G. B. Howarth, D. G. Lance, W. A. Szarek, and J. K. N. Jones, Can. J. Chem., 47, 75 (1969); X. Wang and P. H. Gross, Justus Liebigs Ann. Chem., p. 1367 (1995); N. Ono, M. Bougauchi, and K. Maruyama, Tetrahedron Lett. 33, 1629 (1992). 70. J. M. J. Tronchet, K. D. Pallie, and F. Barbalat-Rey, J. Carbohydr. Chem. 4, 29 (1985). 71. K. Brewster, J. M. Harrison, T. D. Inch, and N. Williams, J. Chem. Soc., Perkin Trans. 1, p. 21 (1987). 72. W. S. Chilton, W. C. Lontz, R. B. Roy, and C. Yoda, J. Org. Chem. 21, 3222 (1971). 73. M. Mancera, E. Rodriguez, I. Roff6, and J. A. Galbis, J. Org. Chem. 53, 5648 (1988). 74. J. C. Sowden, J. Am. Chem. Soc. 72, 3225 (1950); J. C. Sowden and D. R. Strobach, J. Am. Chem. Soc. 80, 2532 (1958). 75. T. Suami, K. Tadano, A. Suga, and Y. Ueno, J. Carbohydr. Chem. 3, 429 (1984). 76. V. Wehner and V. J~iger, Angew. Chem. 102, 1180 (1990); Angew. Chem., Int. Ed. Engl. 29, 1169 (1990). 77. V. I. Kornilov, B. B. Paidak, and Ju. A. Zhdanov, Zh. Obshch. Khim. 43, 189 (1973). 78. G. Just and P. Potvin, Can. J. Chem. 58, 2173 (1980). 79. I. F. Pelyvfis, C. Monneret, and P. Herczegh, Synthetic Aspects of Aminodeoxy Sugar of Antibiotics Springer-Verlag, Heidelberg, 1988. 80. S. Brand~inge and B. Lindquist, Acta Chem. Scand. Ser. B B39, 589 (1985). 81. S. Hanessian and J. Kloss, Tetrahedron Lett. 26, 1261 (1985). 82. M. P. Maguire, P. L. Feldman, and H. Rapoport, J. Org. Chem. 55, 948 (1990). 83. B. J. Magerlein, Tetrahedron Lett. 11, 33 (1970). 84. Y. Fukuda, H. Sasi, and T. Suami, Bull. Chem. Soc. Jpn. 54, 1830 (1981). 85. K. Kanai, J. Nishigaki, S. Ogawa, and T Suami, Bull. Chem. Soc. Jpn. 60, 261 (1987). 86. Y. Fukuda, H. Sasai, and T. Suami, Bull. Chem. Soc. Jpn. 54, 1830 (1981). 87. O. Sakanaka, T. Ohmori, S. Kozaki, T. Suami, T. Ishii, S. Ohba, and Y Saito, Bull. Chem. Soc. Jpn. 59, 1753 (1986); O. Sakanaka, T. Ohmori, S. Kozaki, and T. Suami, ibid., p. 3523. 88. S. Nishimura, Bull. Chem. Soc. Jpn. 32, 61 (1959). 89. Y. Fukuda, H. Kitasato, H. Sasai, and T. Suami, Bull. Chem. Soc. Jpn. 55, 880 (1982). 90. Y. Fukuda, H. Sasai, and T. Suami, Bull. Chem. Soc. Jpn. 55, 1574 (1982). 91. H. Asai, K. Matsuno, and T. Suami, J. Carbohydr. Chem. 4, 99 (1985). 92. T. Suami, Y. Fukuda, J. Yamamoto, Y. Saito, M. Ito, and S. Ohba, J. Carbohydr. Chem. 1, 9 (1982). 93. E.W. Colwin, A. K. Beck, and D. Seebach, Helv. Chim. Acta 64, 2264 (1981); D. Seebach, A. K. Beck, T. Mukhopadhay, and E. Thomas, ibid. 65, 1101 (1982). 94. O. R. Martin, F. E. Khamis, H. A. E1-Shenawy, and S. P. Rao, Tetrahedron Lett. 30, 6139 (1989). 95. A. G. M. Barrett and S. A. Lebold, J. Org. Chem. 55, 3853 (1990). 96. B. Aebischer and A. Vasella, Helv. Chim. Acta 66, 789 (1983). 97. B. Aebischer, J. H. Bieri, R. Prewo, and A. Vasella, Helv. Chim. Acta 65, 2251 (1982). 98. F. Baumberger and A. Vasella, Helv. Chim. Acta 66, 2210 (1983). 99. R. Julina, I. Mailer, A. Vasella, and R. Wyler, Carbohydr. Res. 164, 415 (1987). 100. M. H. D. Postema, Tetrahedron 48, 8545 (1992). 101. K. N. Drew and P. H. Gross, Tetrahedron 47, 6113 (1991). 102. X. Wang and P. H. Gross, J. Org. Chem. 60, 1201 (1995).

72


103. M. Petrugov~, E. Lattov~i, M. Matulov~i, and L. Petrug, Chem. Papers 45, 120 (1992). 104. M. Petrug and J. N. BeMiller, Carbohydr. Res. 230, 197 (1992). 105. P. K611, J. Kopf, M. Morf, B. Zimmer, M. Petrugov~i, and L. Petrug, Carbohydr. Res. 224, 273 (1992). 106. O. R. Martin, F. E. Khamis, and S. P. Rao, Tetrahedron Lett. 30, 6143 (1989). 107. O. R. Martin and W. Lai, J. Org. Chem. 58, 176 (1993).

1.2.4. C h a i n E x t e n s i o n w i t h D i a z o a l k a n e s

1.2.4.1. Hydrolysis of Diazoketones

The chain extension methodology leading through diazoketones (Fig. 1.57) is based on the well-known transformation 1 of acid halides (57.1) with diazoalkanes (57.2), and involves conversion of the diazoketone (57.3) thus produced into halogenoketoses (57.4), ketoses (57.5), or deoxyketoses (57.6) by treatment with hydrogen halides, or acetic acid or by applying simple hydrolytic conditions, respectively. The reaction of aldonic acid chlorides with excess diazomethane proceeds easily; for example, 2,3,4,5,6-penta-O-acetyl-D-gluconyl chloride (58.1) readily gives 3,4,5,6,7-penta-O-acetyl-l-deoxy-l-diazo-D-glucoheptulose (58.2) in moderate yield, 2 as shown in Figure 1.58. 3,4,5,6,7-Penta-O-acetyl-l-deoxy-l-diazo-D-gluco-heptulose (58.2) 2 To a solution of diazomethane (2.1 g, 0.23 mol) in dry ether a solution of the chloride 58.1 (5 g, 10 mmol) in 50 ml of dry ether is added dropwise with stirring at 0~ After remaining at room temperature for 3 h, the solvent is distilled off to result in the crystallization of the product on cooling. The pure diazoketone 58.2 (2.5 g) is

R-CH(OR')--COCI

+

R"CHN2

57.1

57.2

lo

II R-CH(OR')--C-?N 2 + :"

R"CH2CI +

N2

R"

57.3

I HOAc

R"-CH-X CH(OR') I R 57.4

R" - CHOAc

~,~+

R"-CH 2

CH(OR3 I R

ell(OR') I R

57.5

57.6

FIGURE 1.57

1.2. BUILDUP OF SUGARSWITH ASCENDING SYNTHESIS

O~c.tC I _~OAc

ACO [__OAc

CHN2 O ~ OAc ~ ACO-- 1 [.-.--OAc

+ CH2N2

[--OAc t ~ OAc

FOAc ~ OAc

58.1

58.2

.c,/

73

COOH CH I1I HC

Ag20

,

ACO

OAc OAc OAc 58.5

\.o c

CH2Cl

CH2OAC

OAc

OAc

co- 1 I-o c

Aco-1 l-O c

l-o c

]-o c

t--- OAc

L---OAc

58.4

58.3 FIGURE

1.58

obtained after recrystallization from ether, m.p. 106-106.5~ in chloroform).

[a]~ +65.8 (c = 4

An analogous reaction of diacetyl-L-tartaric chloride gives rise 3 to the 1-methyl ester of L-threo-di-O-acetyl-5-diazo-5-deoxy-4-pentulonic acid. On treatment with hydrogen halides or acetic acid, the diazoketone produced in the reaction is transformed into the corresponding halogenomethyl 4 or acetoxy ketone, 5 and such conversions are illustrated, again, through the example of the diazoglucoheptulose (58.2) (Fig. 1.58). 3,4,5,6,7-Penta-O-acetyl-l-chloro-l-deoxy-D-gluco-heptulose (58.3) 4 One gram of the diazoketone 58.2 is suspended in ether (15 ml), and dry hydrochloric acid gas is passed through until a clear solution is produced. It is kept at room temperature for 2 h, the excess HC1 is removed by extraction with aqueous sodium hydrogencarbonate, the organic phase is dried (NazSO4) and diluted with the same volume of petroleum ether, and the precipitated crystals are filtered and washed with petroleum ether to isolate 0.6 g of 58.3, m.p. 100-101~ [a]~ -5.5 (c = 5 in chloroform). 1,3,4,5,6,7-Hexa-O-acetyl-D-gluco-heptulose (5&4) 5 A solution of the diazoketone 58.2 (5.0 g) in acetic anhydride (100 ml) is boiled under reflux for 10-15 min until no evolution of nitrogen is observed (in the drop-counter tube equipped on top of the condenser). The hot reaction mixture is poured onto crushed ice and extracted with chloroform (4 • 50 ml). The organic layer is washed until neutral, dried over CaSO4, and decolorized with carbon. Removal of the solvent results in the spontaneous crystallization of the product 58.4 as yellow needles, which are

74

I ASCENDINGSYNTHESISOF MONOSACCHARIDES recrystallized from 60 ml of i : 4 ethanol-water, and diluted with the same volume of hot water. Yield 3.7 g (70%), m.p. 103.5-105~ [c~]~ + 18.7 (c = 2.7 in chloroform). Following three further recrystallizations, highly pure product is obtained with m.p. 104-105~ [c~]~ +18.7 (c = 2.7 in chloroform).

The same sugar (58.4) is obtained when the bromo analog of 58.3 is submitted to similar exchange reaction. The present procedure allows simple syntheses of the following keto sugars: D-erythrulose, 6 D-ribulose, 7 D-sorbose, 8 L-sorbose, 9 D-fructose, 4 L-fructose, l~ D-psicose, 11 D-galacto-heptulose (D-perseulose), ~2 L-galactoheptulose (L-perseulose), 13 L-manno-heptulose, 14 D-altro-heptulose, 15 D-glycero-D-gulo-octulose, 16 D-galacto-octulose, 17 D-glycero-L-mannooctulose, 18 D-glycero-L-gluco-octulose, 18 D-glycero-D-galacto-octulose, 19 D-erythro-L-manno-nonulose, 2~ and D-erythro-L-gluco-nonulose. 2~ The diazoketones, derived from diazoalkanes, readily undergo silver oxide-induced Wolff rearrangement 21 to lead to unsaturated acids via elimination. For example, related transformation of the diazoketone 58.2 gives 4,22 4,5,6,7-tetraacetoxy-D-arabino-hept-2-enoic acid 58.5, as shown in Figure 1.58. 4,5,6-Tri-O-acetyl-2,3-dideoxy-L-threo-hex-2-enoic acid (59.3), the key intermediate 9 to rhodinose, can be obtained in a similar fashion, specifically, from the 1-diazo-hex-2-ulose (59.2), available from the acid chloride 59.1 derived from L-xylose (Fig. 1.59). 3,4,5,6-Tetra-O-acetyl-l-deoxy-l-diazo-L-xylo-hex-2-ulose (59.2) 9 A solution of 2,3,4,5-tetra-O-acetyl-L-xylonyl chloride (59.1) in dry ether is added dropwise to an ethereal solution of diazomethane prepared from 6.1 g of nitrosomethyl urea. Crystallization of the product starts immediately and is complete on cooling. Recrystallization from acetone-ether affords pure 59.2 (7.4 g, 91%), m.p. 124-126~ [c~]~ - 4 5 (c = 1.09 in chloroform). 4,5,6-Tri-O-acetyl-2,3-dideoxy-L-threo-hex-2-enoic acid (59.3) 9 To a suspension of 59.2 (2.6 g) in water (100 ml) freshly prepared silver oxide (0.5 g) is added at 65~ When the gas evolution is finished, a further amount of the catalyst (0.5 g) is gradually added over a period of 45 min. The mixture is filtered, treated with Amberlite IR-120 (H +), concentrated to 30 ml, and extracted with chloroform. The organic layer is dried and concentrated, and the residue is purified on a silicagel

OliN2

COCl AcO ~----OAc AcO----~ L.__ OAc 59.1

CH2N2

+O

9 AcO FOAc

AcO'---~ u..._ OAc 59.2

F I G U R E I.S9

~O2H Ag20

GH

"

HC FOAc AcO-- 1 u._ 59.3

OAc

1.2. BUILDUP OF SUGARSWITH ASCENDING SYNTHESIS HN2 O OAc

?O2H CH II HC

Ag20 ;

AcO----~

75

AcO

AcO----]

4

AcO--~_

L..._ OAc

OAc

60.1

60.2

FIGURE 1.60

column (eluant: 40 : 1 dichloromethane-methanol) to Obtain pure 59.3 (1.0 g, 48%) as a colorless syrup, [a]~ -26.8 (c = 2.25 in chloroform). F r o m 3,4,5,6- tetra- O - acetyl- 1 - diazo - 1 - deoxy- L-arab ino - hex- 2- ulose (60.1) 4,5,6-tri-O-acetyl-2,3-dideoxy-L-erythro-hex-2-enoic acid (60.2) can be obtained 22 in a similar m a n n e r (Fig. 1.60). The diazoketone derivatives of sugars can be readily transformed into the corresponding methyl ethers on t r e a t m e n t with methanol in the presence of boron trifluoride etherate. Thus, from 7,8-dideoxy-7-diazo-l,2:3,4di-O-isopropylidene-a-D-galacto-6-octulopyranose (61.1), the two 7 - 0 methyl ethers (61.2 and 61,3) are obtained 17 (Fig. 1.61).

1.2.4.2. Addition of Diazomethane to

aldehydo-Sugars

Homologization of aldehydes to ketones can also be achieved by the addition of diazoalkanes to aldehydes. The intermediate of such a noncatalyzed process 23 (Fig. 1.62) is a betaine-type c o m p o u n d (62.1), which is most susceptible to loss of nitrogen, giving rise to the methylketone 62.2 or, as a by-product, the respective anhydro derivative (62.3). The progress of this reaction has been studied 24 in detail with 2,3-0isopropylidene-D-glyceraldehyde, with respect to, for instance, the influence of the solvent. Addition of diazomethane produced 1-deoxy-3,4-O-isopropylidene-D-glycero-tetrulose as the major product. The reaction of this aldehyde with methyl diazoacetate has also been studied. It has been found H CN2

OH3 CH30"~

Oo

/~o,S

/ll ~ OH3

CH3

cH~

o--~c~ R=

OH3

OH3 61.1

61.2

FIGURE 1.61

61.3

76

i


R--C~

\\ O

~

+ CH~--N_=N

~

R--C

H

/

(~

9 62.1

R

R--C

CH

(~

,~CH 2

o

)

62.3

I; 'cm @

/CH3 R--CH~---C\ O 62.2

F I G U R E 1.62

that the noncatalyzed process gives an 84:16 mixture of the (3S,4R)- and (3R,4R)-4,5-O-isopropylidene-2-diazo-3,4,5-trihydroxypentanoates, and this is explained by an easier approach of the reagent from the si side in the more favorable conformation of the aldehydo compound. 25 In practice, this conversion has turned out to be rather useful for a saccharide derivative whose structure has recently been revised. Thus, Grindley 26 showed that the structure of the extended-chain sugar obtained according to the Brigl procedure 27 from "tetrabenzoyl-aldehydo-D-glucose" (63.1) must be as depicted by formula 63.2 (Fig. 1.63). In a similar, easily reproducible reaction, methyl di-O-acetyl-L-threuronate (64.1) can be converted 3 to methyl 2,3-di-O-acetyl-5-deoxy-L-threo-4-penturonate (64.2), as shown in Figure 1.64. Further homologization can be conveniently achieved if excess diazomethane is employed in the chain-extension procedure. For example, from the enantiomeric 2,3,4,5-tetra-O-acetyl-aldehydo-arabinoses,4,5,6,7-tetraCH 3

CHO

HO@OBz --OBz

--O

CH2N 2 - N2

hCH2OBz OBz

--OBz HO---OBz --OBz --OBz

63.1

63.2

F I G U R E 1.63

1'2. BUILDUPOF SUGARSWITH ASCENDING SYNTHESIS

77

OH3

CHO

--O

CH2N2

~OAc AcO

--OA c AcO

CO2CH3

CO2CH3 64.2

64.1

FIGURE 1.64

O-acetyl-l,2-dideoxy-D- and L-arabino-heptuloses h a v e b e e n p r e p a r e d . 28 A n a n a l o g o u s p r o c e d u r e (Fig. 1.65) with the aldehydo-galactose 65.1 serves for a c o n v e n i e n t synthesis 29 of 4,5,6,7,8-penta-O-acetyl-l,2-dideoxy-D-

galacto-octulose (65.2). 4,5,6,7,8-Penta-O-acetyl-l,2-dideoxy-o-galacto-octulose(65,2) 29 A solution of penta-O-acetyl-aldehydo-D-galactose(65.1, 8 g) in dry chloroform is treated with 2.2 M ethereal diazomethane with cooling, and the mixture is left at room temperature overnight. It is then filtered, and the filtrate is concentrated to a syrup, which crystallizes on trituration (yield: 7.0 g, m.p. 97-100~ Recrystallization from a sixfold volume of 50% aqueous ethanol gives small plates of pure 65.2 (5.4 g), m.p. 99-100~ [a]~ -10 (c - 4 in chloroform). In m o d e r n c a r b o h y d r a t e chemistry the chain extensions with diazoalk a n e s play an i m p o r t a n t role in the synthesis of C-disaccharides as well, since an a p p r o p r i a t e diazosaccharide is an excellent r e a c t i o n p a r t n e r for the e x t e n s i o n of the sugar chain with a l o n g e r unit. Spanish chemists 3~ b a s e d the synthesis of the key i n t e r m e d i a t e to 2-deoxytunicamine on a r e l a t e d p r o c e d u r e (Fig. 1.66). Thus, 6-diazo-6-deoxy-l,2;3,4-di-O-isopropyli d e n e - D - g a l a c t o p y r a n o s e (66.1), available in a few simple steps, was r e a c t e d with m e t h y l 2,3-O-isopropylidene-B-o-ribo-pentodialdo-l,4-furanose (66.2) to o b t a i n a m i x t u r e of the C-disaccharide k e t o n e 66.3 and the e p o x i d e 66.4 in a g r e e m e n t with those discussed in the i n t r o d u c t i o n of this section. F r o m the a n h y d r o sugar (66.4), the target c o m p o u n d , 2-deoxy-tunicamine, was p r e p a r e d in a s t r a i g h t f o r w a r d w a y ? ~ H

H "C ~.O

OH2 m O

OAc AcO - -

+ 2 CH2N2

AcO OAc

mOAc AcO AcO ~

CH2OAc

65.1

L'o,~c

65.2

FIGURE 1.65

OAc

78

I


o-~c.~ CH3

H~c~N2

CHO

CH30-~.,, I~

o-yc.

H3C

OH3

66.1

o

"O

O--'4""~~/O

o

~

OH3 CH3

66.2

CH 3

"~-,,r'O

OH3

....

66.3

o-~c.~ OH3

CH300 ~ ' ~ " 0

0 4 y

''q 0

OH3

CHa 66.4

F I G U R E 1.66

Condensation of 6-diazo-6-deoxy-l,2:3,4-di-O-isopropylidene-D-galactopyranose (66.1) w i t h m e t h y l 2,3-O-isopropylidene-~-o-ribo-pentodialdo-l,4-furanoside (66.2) 3~ To a solution of the furanoside 66.2 (1 g) in ether (10 ml) a solution of the diazo compound (66.1) (1.7 g) is added dropwise at 0~ After stirring for 6 h, the reaction is complete, and column chromatography of the crude mixture on silicagel (eluant: 10 : 1 hexane-ethyl acetate) provides 1.8 g (82%) of an unresolvable 1 : 1 mixture of two products. Crystallization of this mixture from hexane-ethyl acetate gives methyl 5-C-(6-deoxy-l,2:3,4-di-O-isopropylidene-I>galactopyranos6-yl)-5-keto-2,3-O-isopropylidene-/3-o-ribo-furanoside (66.3), m.p. 124~ [c~]~ -108.2 (c = 3.31 in chloroform), and methyl (1,2:3,4:9,10-tri-O-isopropylidene-6,7-

anhy dr ~-L-glycer~-L-all~-~-galact~-undec~dia~d~-1~5-pyran~si de )-11~8-/~-furan~side (66.4), [~]~ -66.0 (c = 0.5 in chloroform).

For the execution of C - - C chain extension with a diazoketone, a catalytic procedure has also been elaborated by Kametani and coworkers. 31 This methodology is based on the rhodium(II)acetate-induced generation of a carbene, which ensures chain extension with phenyl thioglycosides. The advantages of this procedure are: (1) the use of phenyl thioglycosides as starting materials can restrict the reaction site by the preferential participation of the sulfur atom with the carbenoid, (2) the introduction of various functionalities can be accomplished by manipulation of the organosulfur groups of the product, (3) the reaction can be performed under neutral condition, and (4) the C - - C bond formation would be stereoselective if this


~

reaction p r o c e e d e d via the o x o n i u m i n t e r m e d i a t e g e n e r a t e d by a p r o p o s e d reaction m e c h a n i s m as shown in Figure 1.67. General procedure for the intermolecular carbenoid displacement reaction 31 A

solution of 1 mmol of the protected thioglycoside and 3 eq of dimethyl c~-diazomalonate (474 mg) in methylene chloride (20 ml) in the presence of rhodium(II)acetate (30 mg) is refluxed for 2 h. After evaporation of the solvent, the residue is chromatographed on a silicagel column using benzene-ethyl acetate to give the C-glycosyl compounds. R e l a t e d C-glycosylation of a few thioglycosides is shown in Fig. 1.68 Ethyl diazopyruvate could also be e m p l o y e d for the chain extension of mono-saccharides in a Lewis acid-catalyzed process, which gives rise to the esters of 2,4-diketocarboxylic acids. According to Herczegh, 32 the SnC12catalyzed reaction provides the products as shown by the e q u a t i o n below: SnC12

R - - C H O + N2CHCOCO2C2H5 ~

-

R--C(O)=C(OH)-C(O)OC2H5

Chain extension of aldehydo-sugar derivatives with ethyl diazopyruvate in a catalyzed process 32 To a solution of the aldehyde (4 mmol) and ethyl diazopyruvate

(4.1 mmol) in dichloromethane (10 ml), tin(II)chloride (70 mg, 0.37 mmol) is added and the mixture is stirred at room temperature for 3 h. After dilution with the same solvent (50 ml), it is washed successively with saturated aqueous NaHCO3 and dilute EDTA solutions. The product is filtered on Kieselgel 60 using 7:3 hexane-ethyl acetate and then 95:5 dichlorormethane-methanol mixtures. W h e n the h y d r o x y a l d e h y d e s carry benzyl protecting groups, the relative quantity of the p r i m a r y products is decreased and secondary processes may p r e d o m i n a t e , to result in ethyl 2-hydroxytetrahydrofuran-2-carboxylates. It is interesting to note that such conversions, catalyzed by b o r o n trifluoride etherate, are carried out 33,34 with the p r e p o n d e r a n c e of the cyclic products even at t e m p e r a t u r e s as low as - 7 8 ~

pO

SR

+

/ N2C

00202H 5

Rh(OAc)2 -

- N2

~00202H 5

SR

--O CO202H5 00262H5

!

9 *

sR

9 ) " 0~

' cO2c2H5 00202H 5

FIGURE 1.67

/ (ACO)2Rh=C\

00262H 5 00202H 5

80

I ASCENDING SYNTHESIS OF MONOSACCHARIDES Substrates

Products

oys,

Yields (%)

E9 = CO2CH 3

OR

SPh

R = Ac R = Bn

R = Ac R = Bn

84 47 SPh

O AcO~

o

AcO[~

SPh

I

AcO \

57

v

!

OAc

OAc

SPh r----OAc L...E

,F-~ ~ SPh

,O~AcACi~ AcO ~J v

E

47

SPh

co .o 0

E

E E

28

0

o

H3cXcH3

o

H3CXCH3

FIGURE 1.68

REFERENCES

TO SECTION

1.2.4

1. B. Eistert, in Neuere Methoden der priiparativen organischen Chemie Vol. /, p. 395. Verlag Chemie, Berlin, 1944; W. Ried, Fortschr. Chem. Forsch. 5, 1 (1965); G. Hilgetag and A. Martini, Weygand/Hilgetag, Organisch-chemische Experimentierkunst, p. 982. Barth Verlag, Leipzig, 1970; A. L. Fridman, T. S. Issmailova, V. S. Salesov, and S. S. Novikov, Usp. Khim. 41 722 (1972). 2. M. L. Wolfrom, D. I. Weisblat, W. H. Zophy, and S. W. Waisbrot, J. Am. Chem. Soc. 63, 201 (1941).

1.2. REFERENCES

81

3. A. J. Ult6e and J. B. J. Soons, RecL Tray. Chim. Pays-Bas 71, 565 (1952); F. Weygand and R. Schmiechen, Chem. Ber. 92, 535 (1959). 4. M. L. Wolfrom, S. M. Waisbrot, and R. L. Brown, J. Am. Chem. Soc. 64, 1701 (1942). 5. M. L. Wolfrom, S. W. Waisbrot, and R. L. Brown, J. Am. Chem. Soc. 64, 2329 (1942). 6. K. Iwadare, BulL Chem. Soc. Jpn. 14, 131 (1939); M. L. Wolfrom and R. B. Bennett, J. Org. Chem. 30, 458 (1965). 7. D. L. MacDonald, J. D. Crum, and R. Barker, J. Am. Chem. Soc. 80, 3379 (1958). 8. M. L. Wolfrom, S. M. Olin, and E. F. Evans, J. Am. Chem. Soc. 66, 204 (1944). 9. W. J. Humphlett, Carbohydr. Res. 7, 431 (1968); R. Knollmann and I. Dyong, Chem. Ber. 108, 2021 (1975). 10. M. L. Wolfrom and A. Thompson, J. Am. Chem. Soc. 68, 791 (1946). 11. M. L. Wolfrom, A. Thompson, and E. F. Evans, J. Am. Chem. Soc. 67, 1793 (1945). 12. M. L. Wolfrom, R. L. Brown, and E. F. Evans, J. Am. Chem. Soc. 65, 1021 (1943). 13. M. L. Wolfrom, J. M. Berkebile, and A. Thompson, J. Am. Chem. Soc. 71, 2360 (1949). 14. M. L. Wolfrom and H. B. Wood, J. Am. Chem. Soc. 73, 730 (1951). 15. M. L. Wolfrom, J. M. Berkebile, and A, Thompson, J. Am. Chem. Soc. 74, 2197 (1952). i6. M. L. Wolfrom and A. Thompson, J. Am. Chem. Soc. 68, 1453 (1946). 17. S. M. David, Carbohydr. Res. 38, 147 (1974); S. M. David and J.-C. Fischer, ibid. 50, 239 (1976). 18. M. L. Wolfrom and P. W. Cooper, J. Am. Chem. Soc. 71, 2668 (1948). 19. M. L. Wolfrom and P. W. Cooper, J. Am. Chem. Soc. 72, 1345 (1950). 20. M. L. Wolfrom and H. B. Wood, J. Am. Chem. Soc. 77, 3096 (1955). 21. L. Wolff, Justus Liebigs Ann. Chem. 394, 23 (1912). 22. D. Charon, Carbohydr. Res. 11, 447 (1969); I. Dyong and W. vonder Heydt, Justus Liebigs Ann. Chem. 735, 138 (1970); R. A. Gakhokidse, N. N. Sidamonidse, and Ch. W. Tan, Zh. Obshch. Khim. 58, 911 (1988). 23. B. Eistert, Neuere Methoden der pri~parativen organischen Chemie I, pp. 359-402. Verlag Chemie, Berlin, 1944; C. D. Gutsche, Org. React. (N. Y.) 8, 394 (1954). 24. S. Hagen, T. Anthonsen, and L. Kilaas, Tetrahedron 35, 2583 (1979). 25. F. J. L6pez-Herrera, M. Valpuesta-Fern~indez, and S. Garcia-Clacos, Tetrahedron 46, 7165 (1990). 26. T. B. Grindley and R. Ponnampalam, Can. J. Chem. 58, 1365 (1980). 27. P. Brigl, H. Mtihlschlegel, and R. Schinle, Ber. Dtsch. Chem. Ges. 64, 2921 (1931). 28. M. L. Wolfrom, J. D. Crum, J. B. Miller, and D. I. Weisblat, J. Am. Chem. Soc. 81, 243 (1959). 29. M. L. Wolfrom, D. J. Weisblat, E. F. Evans, and J. B. Miller, J. Am. Chem. Soc. 79, 6454 (1957). 30. F. Sarabia-Garcia, F. J. L6pez-Herrera, and M. S. Pino Gonz~ilez, Tetrahedron 51, 5491 (1995); F. J. L6pez-Herrera, F. Sarabia-Garcia, and M. S. Pino Gonz~ilez, Tetrahedron Lett. 35, 2933 (1994); F. Sarabia-Garcia and F. J. L6pez-Herrera, Tetrahedron 52, 4757 (1996). 31. T. Kametani, K. Kawamura, and T. Honda, J. Am. Chem. Soc. 109, 3010 (1987). 32. P. Herczegh, I. Kov~ics, L. Szil~igyi, and F. Sztaricskai, Synlett, p. 705 (1991). 33. S. R. Angle, G. P. Wei, Y. K. Ko, and K. Kubo, J. Am. Chem. Soc. 117, 8041 (1995). 34. D. D. Dhavale, N. N. Bhujbal, P. Joshi, and S. G. Desai, Carbohydr. Res. 263, 303 (1994).

1.2.5. Chain Extension with Malonester Derivatives T h i s m e t h o d is b a s e d I o n t h e K n o e v e n a g e l c o n d e n s a t i o n o f a l d e h y d e s a n d ketones with compounds containing an active methylene group, to result in u n s a t u r a t e d c a r b o x y l i c a c i d d e r i v a t i v e s s u s c e p t i b l e of t r a n s f o r m a t i o n s to aldoses 2 with higher c a r b o n chains:


82 R--CHO

>

R--CH--CH--COR'

>

R--CHOH--CHOH--CO2R' R - - C H O H - - C H O H - - CHO

This section also includes the reaction of the salts of active methylene compounds with glycosyl halides, as the products of such transformations are the same as those depicted by the preceding equation, as well as those of a related Wittig reaction (see Section 1.2.6), as shown in Figure 1.69. This type of ring-chain isomerization then explains the term "C-glycosidic compound" applied for the products existing in the cyclic form.

1.2.5.1. Condensation of Open-Chain Monosaccharides with Active Methylene Compounds (Knoevenagel-Doebner Reaction) The aldehydo-derivatives of monosaccharides readily react 2 with malonic acid in pyridine in the presence of a catalytic amount of piperidine. General procedure for the condensation of aldehydo-alkylidene monoses with malonic acid 2 A mixture of 0.04 mol of the alkylidene-aldehydo sugar derivative, 0.045 mol of malonic acid, and a few drops of piperidine (--~1%) in dry pyridine is warmed to 100~ for 0.5-1 h. It is then kept at room temperature for overnight, concentrated under diminished pressure, and recrystallized from the appropriate

oyoyo OR

H..c~O OR

OR

OH

OR

OR

c. X

I R O - ~ O,,,,~ OR

/X HC--C~y OR OR OH OH

IX CH~y

OR

Na

9 1 6 9I X CH~ y

RO~/'~O'~Hal OR

FIGURE 1'69

OR

1.2. BUILDUPOF SUGARSWITH ASCENDINGSYNTHESIS

83

solvent (see Table 1.11). Hydrolysis of the acetal protecting groups can be achieved on hydrolysis with 25-30 parts of 50% acetic acid at 100~ for 30 min. W h e n an e s t e r of m a l o n i c acid is e m p l o y e d for the c o n d e n s a t i o n reaction, no d e c a r b o x y l a t i o n of t h e p r o d u c t occurs a n d t h e c o m p o u n d s s h o w n in T a b l e 1.122-4 (see also T a b l e 1.11), can b e s y n t h e s i z e d a c c o r d i n g to the following e q u a t i o n : + CHz(CO2CH3)2--> R - - C H = C H ( C O a C H 3 ) 2

R--CHO

+ HaO

General procedure for preparation of Knoevenagel condensation products from aldehydo sugars and diethyl malonate5 A mixture of the aldehydo-sugar (17.6 mmol), dimethyl malonate (20.1 ml, 76 mmol), and acetic anhydride (63 ml) in pyridine (90 ml) is kept at room temperature for 36 h. It is then diluted with ethyl

TABLE I . I I KnoevenageI-Doebner Condensation with Open-Chain Monosaccharides

Physical parameters Yield (%)

/t/---CO2H

OH] OHj

I

[~]D

175 (EtOH)

-18.3 (c = 0.87, H20)

Amorphous (ionexchange chromatographic purification) 203-205 (heptane)

-15.8 (c = 1.01, pyridine)

i

OH

OH OH

i

I I

CO2H

//-

I

OH OH

OH

OH OH

I I

M.p. (~

I I

OH OH

CO2H

//--

I

-19.4 (c = 0.98, H20)

OH CO2H

o

~

o

o

~o

H3C

56

198-198.9 (ether/ hexane)

-131.3 (c = 1.6, CHC13)

26

127-128 (CHC13)

-77 (c = 1, CHC13)

40

93-95 (CHC13)

-55 (c = 1, CHC13)

O@CH 3 H3C

OH H3C

CO2H

H

~ H

CO2H

ReL

TABLE 1.12 Starting material

Condensation Products of aldehydo-Sugars with Dirnethyl Malonates Product

[alg

Methyl (4S,5R,6R)-4,6,7-triacetoxy-5-benzyloxy-2-methoxycarb0ny12-heptenoate Methyl (4S,SS,6R)-4,5,6-tris-benzyloxy-7-[(tertbutyldimethylsilyl)oxy]-2-methoxycarbonyl-2-heptenoate Methyl (4S,5R,6R)-4,5,6-tris-benzyloxy-7-[(tertbutyldiphenylsilyl)oxy]-2-methoxycarbonyl-2-heptenoate 4-O-tert-Butyldiphenylsilyl-2,3-O-isopropylidene-aldehydo-~-Methyl (4S,5R)-6-[(tert-butyldiphenylsilyl)oxy]-4,5erythrose (isopropylideneoxy)-2-methoxycarbonyl-2-hexenoate 3-O-Benzyl-1,2-O-isopropylidene-c~-~-xylo-pentodialdo-1,4-Methyl 3-0-benzyl-5,6-dideoxy-1,2-isopropylidene-6-Cfuranose methoxycarbonyl-a-D-xylo-hepto-1,4-furaneuronate 2,3~-Tri-O-benzyl-5-O-tert-butyldiphenylsilyl-aldehydo-~- Methyl (4R,5S,6R)-4,5,6-tris-benzyloxy-7-[(tertarabinose butyldiphenylsilyl)oxy]-2-methoxycarbonyl-2-heptenoate


~5

acetate and extracted with water (3 x 300 ml). The aqueous phases are, separately, reextracted with 300-300 ml of ethyl acetate, and the combined organic layer is dried (Na2SO4).Following evaporation, the residue is purified by means of column chromatography (eluant: 1 : 3 ethyl acetate-hexane) to obtain syrupy products. K n o e v e n a g e l - D o e b n e r syntheses have also been performed with the monomethyl ester of malonic acid, and the resulting a,/~-unsaturated chainextended products have been shown as very useful for the preparation 6 of the methyl esters of 3-O-methyl aldonic acids by treatment with sodium methoxide. Related chain extension (Fig. 1.70) of 2,3-O-isopropylideneD-glyceraldehyde (70.1) or 2,3:4,5-di-O-isopropylidene-D-arabinose (70.2) give, under very mild conditions, methyl trans-2,3-dideoxy-4,5-O-isopropylidene-D-glycero-pent-2-enoate ([email protected])6 or methyl trans-2,3-dideoxy-4,5:6,7di-O-isopropylidene-D-arabino-hept-2-enoate (70.4)7 respectively. Data in the literature show a many-sided reactivity of 2,3-O-isopropylidene-D-glyceraldehyde in the K n o e v e n a g e l - D o e b n e r condensation reaction. Depending on the reaction conditions, various products are formed with methyl malonate, cyanoacetic acid, or acetoacetic acid, and the structure of the products could be elucidated 8=1~in many cases. In general, it is established that a noncatalyzed reaction of the preceding simple sugar first gives and adduct, which transforms into a furane derivative on treatment with acids. In piperidine-catalyzed condensations, unsaturated compounds are produced and are then converted 11 into trioxaspiro[4.4]non-7-enes at different rates. A similar trend has been observed with the condensations of 2,3:4,5di-O-isopropylidene-aldehydo-D-xylose 12 and 2,3:4,5-di-O-isopropylidenealdehydo-D-arabinose. The latter sugar afforded (Fig. 1.71) an a,fl- (71.1) and a/~,T- (71.2) unsaturated compound and an enol (71.3) as the primary products 13 with acetylacetone. CO2H CH~ Jr

CO2CH3 4-

H .,.c~O

Lo

j. 002CH3

?o LO•

H.~c~.O O~ : ~

LoXcH~

cH3

~o_

CH 3

L ox c.,

70. I

70.2.

~

coc.,

Z__,o.,

9o ~ o ~ C H ;

c., LoXcH,

70. 3

70.4

FIGURE 1.70

86

I ASCENDING SYNTHESIS OF MONOSACCHARIDES CH 3 CH3OC

~C

,COCH 3

II CH O~__J

CH3OC~

/COCH3 CH

HO

I

HC " "

/CH3

LoXc. I-'-- O.

CH 3

CH

Lo>gluco-octulosonate (76.3) 21 A mixture of the aldehydo-xylose derivative 76.2 (3.26 g, 0.01 mol), diethyl oxalacetate (76.1; 1.88 g, 0.01 mol), and diethylamine (0.5 ml) in chloroform (120 ml) is kept at 20~ for 3 days with occasional shaking, and during this time a clear solution is formed. The solvent is distilled off, and the syrupy residue is crystallized from methanol to obtain pure 76.3 (2.10 g, 41%) as needles, m.p. 168169~ [c~]~ +86.1 (c = 1.85 in chloroform).

(2E, 4E)(6R, 7R)-4,6,7,8-Tetradeoxy-2-cyanooctadieneamide--produced in the reaction of D-glucose and cyanoacetamide--is of practical importance as its dehydration products (3-cyano-2-pyridones and 2-cyano-2-pyrrolidones) are UV-light-absorbing, electrochemically oxidizable or fluorescent compounds, useful for postcolumn labelingin high-performance liquid chromatography (HPLC). The acetyl derivative of the chain-extended product is easily available (with 48% yield) in the pyridine-catalyzed Knoevenagel condensation 22 of pentaacetyl-aldehydo-I>glucose with cyanoacetamide. Figure 1.77 shows an interesting chain extension reaction of aldehydosugars, carrying O-benzylidene or isopropylidene protecting groups, with dibutyl cyanomethylphosphonate. According to this procedure, reported by Zhdanov, 23 2,3-dideoxy-2-(dibutoxyphosphonyl)-4,5:6,7-di-O-isopropylidene-L-arabino-heptenonitrile (77.3) can be synthesized from the aldehydo-sugar 77.1 and the cyanomethylphosphonate 77.2. 1.2.5.2. Chain Extension with Malonate Derivatives

The esters of malonic acid are extremely versatile reagents in organic chemistry; therefore, many attempts have been made to prepare their carbohydrate derivatives. Glycosyl halides readily react with malonates under glycosidation conditions, to form a C - - C bond, and thus to produce anhydro-2-deoxy-2-alkoxycarbonylhexonates or-heptonates. Related deriva-

CN 0 I II C _ P(OC4H9_ll)2 II CH ~__~~CH3

H ...C~.,0 O

O

OH3 CH3

+

CN + H2 O~-P(OC4Hg-n)2

H3CX

# O

H3C _O HaGXO 77.1

77.2 FIGURE 1.77

77.3


9 I

tives previously synthesized according to the following equation are collected in Table 1.13. 24-3o

The chain-extended derivatives shown in Table 1.13 can be regarded as C-glycosidic compounds, whose f o r m a t i o n ~ a s well as the ratio of the anomers produced in the reaction~can be influenced 27 by bases, and the use of a very simple reaction step permits the isolation of the thermodynamically more stable product, as shown in the following example. Diethyl 2-(2,3,4,6-tetra-O-benzyl-B-D-glucopyranosyl)-malonate 31 To a solution of diethyl 2-(2,3,4,6-tetra-O-benzyl-a-D-glucopyranosyI)-malonate (1 mmol) in a small volume of methanol is added sodium methoxide in methanol (0.94 mmol, 15 ml), and the reaction is monitored by TLC (4" 1 hexane-ethyl acetate). After 30 min the mixture is neutralized and the crude product is recrystallized from diisopropyl ether-petroleum ether to furnish 88% of the pure/3 anomer, m.p. 50~ [a]~ +3.2 (c = 1 in chloroform).

An additional possibility for synthesizing similar malonester analogs is the reaction of sugar derivatives, carrying a free anomeric hydroxyl group, with the sodium salt of an active methylene compound (malonitrile, cyanoacetate, or malonate). As shown in Figure 1.78, such transformations also provide the C-glycoside of the methylene derivative. 32 General procedure for the preparation of C-glycofuranosyl malonates 32 Method A A solution of the malonic acid derivative (15 retool) in THF (15 ml) is added to a suspension of 50% sodium hydride (720 mg, 15 retool) in dry THF (20 ml) at 0~ in argon atmosphere, and then 5 mmol of the sugar derivative is added. After overnight stirring, the mixture is poured onto saturated aqueous ammonium chloride solution (20 ml) and extracted with dichloromethane (3 • 100 ml). The organic layer is washed with water (2 • 30 ml) and aqueous NaaCO3 (50 ml) and dried over MgSO4. The solvent is distilled off, and the crude product is purified by means of column chromatography (eluant: 1" 12 ethyl acetate-hexane or 4" 1 toluene-ether). Method B To a solution of the sugar derivative (5 mmol) in benzene or dichloromethane (20 ml), 10% aqueous NaOH solution (20 ml) and tetrabutylammonium hydrogensulfate (1.86 g, 5 mmol) are added, followed by the addition of the malonic acid derivative, and the mixture is stirred vigorously for 3 h while monitoring with TLC as shown in method A.

Barbituric acid, the cyclic ureide of malonic acid, also contains an active methylene group, and therefore can be used in chain-extension experiments. Thus, when glucosamine hydrochloride (79.1) is heated with barbituric acid (79.2) in water, 5-(2-amino-2-deoxy-~-D-glucopyranosyl)-barbituric acid (79.3-) is obtained 33 (Fig. 1.79). 5-(2-Amino-2-deoxy-~-o-glucopyranosyl)-barbituric acid (79.3) 33 A solution of D-glucosamine hydrochloride (79.1, 1.1 g, 5 mmol) in water (20 ml) is mixed with sodium carbonate (0.27 g, 2.5 mmol) and barbituric acid (79.2, 0.64 g, 5 retool),

92 TABLE

I ASCENDING SYNTHESISOF MONOSACCHARIDES 1.13

C - G l y c o s y I - M a l o n e s t e r D e r i v a t i v e s O b t a i n e d f r o m Glycosyl Halides ,

Educt

Product O.A;

F

Yield (%)

F'--OAc

1~?Ac ~

/C--"----O CH(CO2C2Hs)2

OAc

r--OAc AC?,/)-- O CH(CO2C2Hs) 2

f0% Ac6",l

OAc - - O CH(CO2CH2"C6Hs) 2 - -

,co( i

81-92

23"77-

24

72" 28

21

--

26

X~

quantitative

9" 1

24

80

9" 1

27

57

--

24

---100 90

9"1 10" 1

27 28

94

12"7

27

~o~'~CH,CO2C2H02

XO-] o

o

~o~'~c.,co2c~H0~

I

H~

TrO---~Cl

24

OBn

o-~o Br

O

--

)Ac 2

Br OBn

~

80-100

~OBn ~ CH(CO2CH2-C6Hs) 2 BnOM ( OBn

j,.o~

~O

25

/oI

j_o~

~[ Br OBn

~o

1.2. BUILDUPOF SUGARSWITH ASCENDING SYNTHESIS O

OH(Z)

[/

HO

I

O

OH @

Ar

OH 3

N

O

95

OH3

--N

Ar-CH2Br OH 3

DMSO

//L-[ O__H 0 "~

~

0 --N O II

H

80.2

\

CH3

OH

Na

I 1. NaOH 2. AcOH 3. Ac20

80.1

Ar

0

I

OAc 80.3

FIGURE 1.80

and among them, conversion into the multifunctionalized C-glycosidic compound 80.3. Zhdanov and Bogdanova 35 have found that the 5-O-glycopyranoside derivatives of barbituric acid are easily available from hexoses (D-glucose, D-mannose, and D-galactose) on treatment of the corresponding aldehydoaldose with barbituric acid in hot aqueous ethanol. 1,3-Dimethylbarbituric acid is a suitable target for conversion, as either the free acid or its sodium salt, into the 5-glycosyl-l,3-dimethylbarbituric acids 81.1 and 81.2 (or their sodium salts) according the the Zhdanov method. Acetylation of these compounds then leads 35 either to cyclic C-glycosidic compounds (such as in the case of D-ribose to furnish 81.3) or to acyclic analogs, such as 81.4, obtained form D-xylose (Fig. 1.81). The observations discussed in the preceding paragraphs have been successfully applied 36 for the synthesis of the C-glycoside-type antibiotic pyrazomycin. The key step in this procedure (Fig. 1.82) is the C - - C bond formation between 2,3-O-isopropylidene-5-O-(p-nitrobenzoyl)-~-Dribofuranosyl bromide (82.1) and the active methylene compound diethyl 1,3-acetonedicarboxylate (82.2), followed by straightforward steps to pyrazomycin (82.7). Condensation of 2,3-O-isopropylidene-5-O-(p-nitrobenzoyl)-~-D-ribofuranosyl bromide (82.1) with diethyl 1,3-acetonedicarboxylate (82.2) 36 T o a stirred s u s p e n -

96

I ASCENDINGSYNTHESISOF MONOSACCHARIDES 0 o

H

1

O

CH 3 / ""N

)=o

N\ CHa

H(~XL__~ O OH

OH OH

CH 3

81.2

81.1

I Ac20

I Ac20

O

o H3C~ N~,,,~ N.,CH3

CH 3

o@o

o

Ac

OH 3

ACOx/~C"H

CHa

- \ OAc OAc

OAc OAc

OAc 81.4

81.3 FIGURE

1.81

sion of potassium hydride (805 mg, 20.1 mmol) in dry benzene (40 ml), 4 ml of diethyl 1,3-acetonedicarboxylate (82.2) is added dropwise under argon atmosphere, followed by a solution of 18-crown-6 (3.75 g, 14.2 mmol) in 30 ml of benzene. After hydrogen evolution has ceased, a larger excess (22 ml) of diethyl 1,3-acetonedicarboxylate is added in one portion. Then, a solution of the ribofuranosyl bromide 82.1 (5.93 g, 14.74 mmol) in 80 ml of dry benzene is added dropwise over a 30 min period. The reaction mixture is stirred under argon at room temperature for 16 h and diluted with ether (1 liter) and the ethereal phase is washed with water (3 • 300 ml), diluted with 300 ml of benzene, and dried over Na2SO4. After evaporation of the solvent under reduced pressure, excess of the reagent 82.2 is distilled off in a bulb-to-bulb apparatus at 80-85~ (0.1 mmHg). The residue is dissolved in a 10:1 mixture of toluene and ethyl acetate (15 ml) and chromatographed on a column containing 550 g of a mixture of 75% of Silicagel 60 and 25% of Silicagel PF254 (both from Merck). The column is developed with the following mixtures of toluene and ethyl acetate: 10:1 (3600 ml, fractions 1-149), 10:1.5 (2300 ml, fractions 150-265) and 10:3 (1300 ml, fractions 266-300). The eluate is monitored by TLC (10:1.75 toluene-ethyl acetate and 3:1 cyclohexane-ethyl acetate). Fractions 80-114: Evaporation and drying in vacuo at 60~ (0.01 mmHg) affords 0.41 g (5.3%) of 3-[2,3-O-isopropylidene-5-O-(p-nitrobenzoyl)-~-D-ribofuranosyl]oxy-2-pentenedioic acid diethyl ester (82.3) as a colorless syrup, [a]~ -96.8 (c = 1.12 in chloroform).

Hod CONH,

HO

OH pyrazomycin 82.7

FIGURE 1.82

98


Fractions 115-188: Evaporation and drying give 2.85 g of 2-[2,3-O-isopropyli-

dene-5-O-(p-nitrobenzoyl)-a-D-ribofuranosyl)-oxoglutaricacid diethyl ester (82.4). An additional 0.45 g of the compound can be obtained on rechromatographing fractions 189-230, giving a total yield of 42.8%, colorless syrup, [a]~ +44.8 (c -0.94 in chloroform). Fractions 231-310: These fractions (combined with the remainder from fractions 189-230) are rechromatographed on 450 g of silicagel mixture (see the preceding

mc_ o-

.~oXo_~.o

H3C_ O'--m

~

H~oXo_r o

~o->o

A, DMF

H2 ;

OH3 OH3

H3d

C--O

109.1

0

5-

OH3 OH3

109.2

H3C ~ C/.,.O

H3C\ C:O O H

KF, 12-Crown-4

H2C~ ~

~IO OCH3

A, DMF CH3 CH3

CH3 CH3 109.4

109.3

F I G U R E 1.109

1.2. BUILDUP OF SUGARS WITH ~,SCENDING SYNTHESIS O.~c/CH =PPha

O..c/CH=PPh3 "~ ~.C '

O

03"~ O(~

''oH3 OH3

H3C

O"~c'/CH=PPh3

9O

Bn?) I~Bn

oo

O . . . ~ CH3

CHO,., +

O 'r--(

O~C..ICH

OCH3

O altro-2,5-anhydro-3,4- O-isopropylidene-6- O-trityldeoxyhexanophosphonate and diphenyl-D-allo-2,5-anhydro-3,4-Oisopropylidene-6-O-trityl-deoxyhexanophosphonate TM (E)-2,3,5-Tri-O-benzyl-l,2-dideoxy-l-diphenylphosphono-4-O-(tert-

b utyl dime th ylsilyl )-D-ribo-h ex- l-enitol. 345 1.2.6.4. Chain Extension of Saccharides with Phosphoryl-Stabilized Carbanions The olefination reaction of various PO-activated reagents can also be used for chain extension. In general, T M such a process involves the formation of an unsaturated compound (117.3) from a PO-activated carbanion (117.1) and an aldehyde (117.2) or ketone with splitting off of the POactivated reagent in the form of the next,higher oxidation state, as shown in Figure 1.117. Application of this methodology, called the Horner-Wittig or Wadsworth-Emmons reaction, is very well documented, for example, in the volumes of Houben-Weyl. 347The supposed mechanism of the PO-activated olefination can be explained by a reaction scheme such as that in Figure 1.118, which demonstrates that the product must be a mixture of the (E)and (Z)-olefins. The attack of the PO-activated carbanion (118.1) on the carbonyl group (118.2) gives rise to an oxyanion (118.3) in a reversible process, which is then transformed into the (E/Z)-olefin 118.5 via a fourcenter intermediate 118.4. The stereochemical outcome of the reaction is determined by the combination of the individual reaction steps.

I 60

I ASCENDING SYNTHESIS OF NONOSACCHARIDES

o

oQ

(5)

II R2P--CH--R 1

I

R2P--CH--R 1 117.1

I ~c.o 117.2

R2--CH--CH-R I

O

+

II R2P--O(Z) 117.4

117.3

FIGURE

I . I 17

1.2.6.4.1. Chain Extension of Saccharides with Phosphonates The reaction of phosphonic acid esters, carrying an activated methylene group at a-position to the phosphorous atom, with carbonyl compounds in the presence of various bases, results in olefins with simultaneous loss of a phosphoric acid ester: R--CH2--P(O)(OR1)2 + R 2 - - C H O

> R - - C H - - C H - - R 2 + HOP(O)(OR1)2

It is known that mainly (E)-olefins are produced 1,348from aldehydes substituted with an electron-withdrawing group and dialkyl phosphonates, but the presence of an oxygen-function at c~- or B-position may infuence the ratio of the geometric isomers.

oo II

~p-c~-~ 118.1

~

|

L

o R2P

~

H H|

_I

~"

:

j

R

~

R2--CHO 118.2

Rf~--XR2

m1

R2P

J

H[

L~~--.~

""

118.4

118.3

FIGURE

I . I 18

118.5


|6|

CO2R' h--o CH LoXcH3

3

+

O Ii (RO)2P--CH2CO2R'

119.1

~

119.2

F--O_ O H 3 L;XcH3

+

CH3 LoXcH3

119.3 FIGURE

119.4

I.I I?

The chain extension of 2,3-O-isopropylidene-D-glyceraldehyde (119.1) with trimethyl phosphonoacetate (119.2) in the presence of sodium hydride leads 348 to 90% of a 7:1 (E/Z) mixture of the unsaturated esters 119.3 and 119.4 (see Fig. 1.119). With ethyl diisopropylphosphonoacetate and potassium tert-butoxide (as the base), this ratio changes 349to 120" 1, whereas the reaction of the sugar 119.1 with the sodium salt of trimethyl phosphonoacetate in THF in the presence of acetic acid gives35~ the (Z)-isomer 119.4 exclusively. In the case of O-benzyl-L-lactaldehyde (120.1), the product distribution can be easily shifted toward the desired stereoisomer by selecting the proper reagent and reaction conditions. With trimethyl phosphonoacetate/NaH, a 1:1 mixture of the chain-extended products (120.2 and 120.3) is obtained. At the same time, the (Z)-pent-2-enoic ester (120.3) is the predominant (E: Z = 1:5) when the reagents are methyl di-O-(/~,~,/3-trifluoroethyl)phosphonate and potassium hexamethyldisilazanide. 351 General procedure for the preparation of methyl (2Z,4S)-4-benyzloxypent-2enoates351 To a mixture of potassium hydride (1 mmol) in dry THF (2 ml) a solution of methyl di-O-(/~,/~,/~-trifluoroethyl)phosphonoacetate (1 retool) in dry THF (2 ml) is added dropwise at -78~ Then a solution of O-benzyl-L-lactaldehyde (1 mmol) in 2 mI of dry THF is added, and stirring is continued for an additional 40 min. The mixture is diluted with ether (3 ml), and the reaction is quenched with aqueous ammonium chloride (3 ml). It is then allowed to warm to room temperature, and the organic layer is separated, washed with aqueous Na2CO3 until neutral,

H.~cr BnO-~ CH3

CO2R'

120.1

~CO2R' BnO-O II (RO)2P--CH2CO2R'

CH3 120.2

F I G U R E I. 120

BnO/ CH3 120.3

162

I ASCENDING SYNTHESIS OF MONOSACCHARIDES H3C CH3

H~C/H3 0 0 H ,n~/~ B ~

H

+

o II

(C2H50)2p _ CH2CO2C2H5

~

DIPEA ~ LiCI

Lit352")

0 0 /,,,,,I__[,,H I \.

Bn

CHO

H" ,l

~00202H 5

F I G U R E 1.121

dried, and concentrated. The residue is submitted to column chromatography with a hexane-ethyl acetate eluant. W h e n this p r o c e d u r e is e x e c u t e d with s o d i u m hydride and triethyl p h o s p h o n o a c e t a t e instead of the r e a g e n t s m e n t i o n e d previously, 2 - ( E ) p r o d u c t s are o b t a i n e d exclusively, and similar results h a v e b e e n o b t a i n e d with the H o r n e r - E m m o n s reactions shown in Figures 1.121 and 1.122. 352.354 T h e chain extension 355 shown in F i g u r e 1.123 is a synthetic r o u t e to a hex-2-enoic acid derivative 123.3, in which the r e a c t i o n p a r t n e r of the starting saccharide 123.1 is the anion g e n e r a t e d f r o m t r i m e t h y l p h o s p h o n o a c e t a t e (123.2). Ethyl 6-[(tert-butyldimethylsilyl)oxy]-4(S),5 (S)-(isopropylidenedioxy)-hex-2 (E)enoate (123.3) 355 To a 60% suspension of sodium hydride (182 mg in mineral oil) in benzene (10 ml), a solution of trimethyl phosphonoacetate (123.2, 827 mg, 4 . 5 4 mmol) in benzene (2 ml) is added at 0~ with stirring. Stirring is continued for an additional 1 h, and then a solution of 4-O-(tert-butyldimethylsilyl)-2,3-Oisopropylidene-L-threose (123.1, 1.245 g, 4.54 mmol) in benzene (4 ml) is added dropwise over a period of 5 min. After stirring for i h, the mixture is poured into 50 ml of ice water, the organic layer is separated, and the aqueous phase is extracted with benzene (3 • 50 ml). The combined organic layer is washed with water, H3C~CH3

H,',,,~ H

C2H502C

H3CxCH3 O O H~ , , ~ H 41, OHC

+

51%

CO2C2H5

O NaH II ~~----t, (C2HsO)2P--CH2CO2C2H 5 _780C H3C~3H3

CHO

HJ,,~

H

Lit353) cf. also 354.) 02H502C 00202H5 F I G U R E 1.122

1.2. BUILDUP OF SUGARS WITH ASCENDING SYNTHESIS H-,.cr H3C_

O----~

HaCXOtoTBDM

123.1

s

0 II (C2HsO)2P--CH2CO2C2H5

NaH HaC_

O

/

] ~3 CO2CH3

H3GXo~__OTBDMs 123.2

FIGURE 1.123

123.3

dried (MgSO4), and concentrated, and the residue is purified by means of column chromatography with a 1" 8 ethyl acetate-hexane eluant to obtain 1.43 g (95%) syrupy 123.3, which contains less than 1% of the (Z)-isomer [a]~ -12.7 (c = 2.3 in methanol). Table 1.24 lists further PO-activated H o r n e r - E m m o n s olefination reactions of saccharides with relatively simple (mostly alkyl-substituted) phosphonates and gives some details on the experimental conditions. 356-378 An important contribution to this field is a procedure for the preparation of higher-carbon sugars, which allows the synthesis of natural products with a longer carbon skeleton (C20, or higher) by the H o r n e r - E m m o n s coupling of saccharide-phosphonic acids with aldehydo-saccharides. To illustrate this methodology, Figure 1.124 shows a convenient route to the C15-enolether 124.3 from the aldehydo-heptose 124.1 and the sugar phosphonate 124.2, as described by Paquet and Sinay. 379 In another related work (Fig. 1.125) Indian authors 38~ have converted four different educts into the sugar-ketophosphonates 125.2, whose H o r n e r - E m m o n s olefination with the aldehydo-saccharides 125.1 led to the long-chain enones (125.3) carrying a sugar moiety at both the carbonyl and the olefinic carbons. These latter compounds, regarded as the sugar analogs of aromatic chalcones, could be obtained by treatment of the ketophosphonates (125.2) with cesium carbonate in 2-propanol. This route was also accessible for the first synthesis of monosaccharide derivatives having 19 and 21 carbon atoms in the skeleton, and among others, the "longest monosaccharide of 1994" (126.3)was prepared 381 from t h e C12-dialdose 126.1 and the C9-phosphonate 126.2, as shown in Figure 1.126. From Figures 1.123-1.126 it is clear that the carbon atoms necessary for the chain extension of a saccharide may arise from sugar-phosphonates, which are generally transformed to the suitable ulose-phosphonates, capable of intramolecular PO-activated olefination. The chain-extended phosphonate 127.2, derived from benzyl 2,3-O-isopropylidene-5-Otrifluoromethanesulfonyl-a-D-lyxofuranoside (127.1), as shown in Figure 1.127, was treated with sodium methoxide, w h e n ~ o n ring-closure~the O-isopropylidene derivative of methyl shikimate (127.3) is produced. 3s2

TABLE 1.24

Chain Extension of Saccharides with Phosphonates

Educt

Product

Reaction conditions, yield

Physical parameters

R=TBDMS

Refs.

357

E : Z = 5 : 1; (E) m.p. 51-52'C 7H3 (Me3Si)2NLi, -78'C

R = CI,CC-CI II CH, 0

THF

E:Z=3:1 HXC+O (CH30),P(0)CH2COCH3, NaH 22 OC, benzene, 30 min 0

83% OBn

(CH,0),P(0)CH2COCH3, 0

NaH

25% toluene

OBn OBn 1, (C2H50)2P(0)CF2H. LDA THF. -78% 2, C6H50C(S)CI 83%

357

CHO 1, (C2H50)2P(0)CF2H, LDA THF, -7E0C 2, CgH50C(S)CI 87% O x 0 H3C CH,

(C2H5O),P(O)CH2C0,C2H5, NaH 2E°C, THF, 1 h 81%

1 eq. LiN(SiMe3)2. THF 70%

1 eq. LiN(SiMe3)2. THF.2Oh 43%

I 0

I 0

H3cXcH3 H,C+O

-

6

0

H3cXcH,

NaH, dimethoxyethane 90 min.. reflux

HC-CN II CH benzene.DMS0 = 3:1, Na2C03 39%

[a]

= -13.2

363

(c = 1, CHCI3)

OI km

(continues)

TABLE I .24

(continued)

-

uOI

Reaction conditions, yield

Product

Educt

NaH, benzene, (RO)2P(0)CH2C02R

Physical parameters

R = CH3 [a]:= -1.1 (C = 3. C ~ H ~ O H )

20°C, Ih

Refs.

364

R = C2H5

[a]

?=

+3.2

(C = 2.5, C2H50H)

with three different methods ,NHZ (CH,O),P(O)HC, C02CH, R = H. Tr. TBDMS

CHO

NaH. (C2H50)2P(0)CH2C02C2H5

OCH, OCH,

THF, 20°C

cf. original publication

365 Further derivatives; 366

OCH, (c,H,o),P(o) HC

CH, '3%

HC CH,

O ~ C H ,

-

I OCH3

OBn 124.2

H

,z

~

INHAc

H3C "I .CH3

rx? j..o BnO "-------rOCH3 H3C" I CH 3

OBn

124.3

F I G U R E I. 124

Additional examples for PO-activated intramolecular olefinations have been reported. 383-389 An easily reproducible procedure for the preparation of sugarphosphonates has been recently reported by Paulsen and von Deyn 39~(see Fig. 1.128). D imeth y l 3, 4,5-tri-O-b en z y l-l -deoxy-6, 7-O-is op rop y lidene- o-gly ce r o- o-gul o-heptitol-l-phosphonate (128.2) and dimethyl 3,4,5-tri-O-benzyl-l-deoxy-6, 7-O-isopropylidene-o-glycero-o-ido-heptitol-l-phosphonate (!28.3) 390 To a solution of dimethyl methylphosphonate (12 ml, 0.11 mol) in dry THF (300 ml), 69 ml of a 1.6 M solution of n-butyllithium in hexane is added dropwise at -78~ under nitrogen atmosphere. The mixture is warmed to room temperature, stirred for 10 min, and cooled again to -78~ and a solution of 2,3,4-tri-O-benzyl-5,6-Oisopropylidene-aldehydo-I>glucose (128.1, 18.3 g, 37.3 mmol) in dry THF (200 ml) is added dropwise and stirring is continued for additional 1 h, when transformation of the aldehydo-sugar has been completed. For workup, 8 ml of acetic acid is added, the mixture is concentrated and redissolved in dichloromethane, and the organic layer is washed with water, dried over MgSO4, and concentrated. The crude syrupy product is purified by means of column chromatography (eluant: 15:1 tolueneethanol) to furnish 20.5 g (89%) of the mixture of 128.2 and 128.3.

Methylene-bisphosphonates are also popular PO-activated reagents in chain-extension reactions. Thus, 2,3:4,5-di-O-isopropylidene-aldehydo-Darabinose (129.1) readily furnishes 1-diethylphosphono-l,2-dideoxy3,4:5,6-di-O-isopropylidene-D-arabino-(E)-hex-l-enitol (129.3) on chain extension 391 (Fig. 1.129) with the anion of diethyl methane-bis-phosphonate (129.2). 1-Diethylphosphono-l,2-dideoxy-3, 4: 5, 6-di-O-isopropylidene-o-arabino-(E)-hex1-enitol (129.3) 391 To a stirred mixture of sodium hydride (145 mg, 60% in mineral oil) in dry ethyleneglycol dimethylether (25 ml), diethyl methane-bis-phosphonate (129.2, 0.35 g, 3.0 mmol) in ethyleneglycol dimethylether (15 ml) is added and the reaction mixture is stirred for i h. After cooling to 10~ a solution of 2,3:4,5-diO-isopropylidene-aldehydo-D-arabinose (129.1, 700 mg, 3 mmol) in ethyleneglycol dimethylether (25 ml) is added, and stirring is continued for an additional 1 h. The mixture is then poured into 250 ml of ice water, extracted with ether (5 • 100 ml), the organic layer is dried (NazSO4) and concentrated, and the crude product

1.2. BUILDUPOF SUGARSWITH ASCENDING SYNTHESIS

'sugar'--CliO

0 II "sugar"--CCH2P(O)(OCH3)2

12,5.1

125.2

0 II 'sugar'--C--CH--CH--"sugar"

~b,

125.3

'suqar'-CHO

H~c~O O

I~ I

"sugar" O /z~0

~

CH3

oXcH3

H3C

O@CH

CH3

CHO n

3

0 O-~--- CH3 CH3

Bn

e I/~OMe OMe

H-,,c~O

bI--- O_o / ~ C HCH3 3 L;XcH

O--"~-- CH3 CH3

3

CHO

H3C OH3

bI----O_O" ~CH3 OH3

O_..~CH3 --

L;XcH

3

OH3 FIGURE

1.125

is crystallized from hot n-pentane to give 800 mg (72%) of the title compound 129.3, m.p. 49-51~ [o~]~ +2.0 (c - 1 in chloroform).

2,4-O-Ethylidene-D-erythrose also gives 391 the (E )-product, with 31% yield, in an analogous reaction. An additional example for a related transformation is the chain extension of 2,3,5-tri-O-benzyl-4-O-(tertbutyldimethylsilyl)-aldehydo-D-arabinose to furnish 345 31% of (E)-2,3,5-tri-

72


~

BnO OBn OBn OBn BnO Bn~,~ CH30

CHO

OBn OBn OBn BnO OBn OBn OBn

B

126.1

toluene 55%

BnO .

~

B

n

O

O OBn

K2CO3, 18-crown-6

+

B

n

9 BnOT.~ O CH30

............

P(O)(OCH3)2

"~/ O~-OBn OCH3 H3C OH3

126.3

nO .'O \?

CH30"-J~

A H3C OH3 126.2

F I G U R E 1.126

1) (CH3)2P(O)CHCO2CH3 TfO ~ O " ~ O ~ o B n

DMF, 50 ~

18-crown-6

O--P(OCH3) 2 ~CO2CH

3

NaOCH 3

2) H2 / Pd-C

~

H 127.1

127.2

H 127.3

F I G U R E 1.127

CH2P(O)(OCH3)2

H.,,c~.O

_~OBn § BnO [__OBn I---0 CHa

LoXcH~

CH2P(O)(OCH3)2

HO-~oBn

OBn LiCH2P(O)(CH3)2

BnO~ I

+

--OBn

LoXcH~ !---O

128.2

128.1

F I G U R E 1.128

CH3

BnO-- i

~ -OBn

LoXcH~ I---O

128.3

OH3


I 7~

(C2HsO)2P(O) #

H"C~"O

O==~CH3

I__O"--CH3

+

C)C~

I-'- O_ OH3 LOXCH3

P(O)(OCH3)2

~

O '==~--~..../CH3 ~- ' O / - C H 3

P(O)(OCH3)2

/oXc.OH3 I---O.

129.3

129.2

129.1

FIGURE 1.129

O-benzyl- 1,2-di deoxy- 1-die thylp hosp hono-4-O-( tert-butyl dime thylsilyl)-

D-ribo-hex-l-enitol. The lithiated fluoromethylene-bis-phosphonate (130.2) has been reported in a preliminary paper 392 as applicable for the chain elongation (Fig. 1.130) of methyl 2,3-O-isopropylidene-fl-D-ribo-pentodialdo-l,4furanoside (131).1) to afford the (E)-vinylphosphonate 130.3 and the rearranged product 130.4. The preparation of several another phosphonates is described by Paquet and Sinay 379 and Paulsen and Bartsch. 393 A novel possibility for PO-activated olefination is associated with the utilization of alkoxyalkyl diarylphosphine oxides (Fig. 1.131). The lithiated cyclohexyloxymethyl diphenylphosphine oxide 131.2 was reacted with 2,3,5tri-O-benzyl-D-arabinose (131.1) in THF solution at -78~ and subsequent treatment with potassium hydride at 40~ resulted in a 1:2 (E/Z) mixture of the enolether 131.3 with 75% yield. 394 The methoxymethyl analog of 131.2 has been employed by Polish chemists 37~for similar transformations, and the chain extension of 2,3,5-tri-O-benzyl-D-arabinose and-D-ribose have been also carried out 395 with the phosphinoxides 132.1 (Fig. 1.132). The sulfonyl- and sulfonylphosphoryl-stabilized carbanions represent the last sub-group of the PO-stabilized carbanions useful for the chain extension of monosaccharides (Fig. 1.133). While Peterson olefination of 2,3-O-isopropylidene-D-glyceraldehyde (133.1) with phenyltrimethylsilylsulfone (133.2) gives 396 72% of an (Z/E) sulfone mixture (133.3 and 133.4), H CHO

.,.O~ CH3

O

~

'

O

(C2H50)2(O)P

+ [(C2H50)2P(O)]2CHLi

O

CH3

_~ 0

~ H3C OH3 130.2

CH3 +

0

H3C OH3 130.1

(02HsO)2(O)P o

130.3 FIGURE 1.130

0

0

~" H3C OH3 130.4

174

I ASCENDINGSYNTHESISOF MONOSACCHARIDES H

BnO---~ ~ 0

1, LDA

(C6Hs)2P(O)CH#O---~~

OBn

2, KH, 40

THF

~

BnO~ ~'0~

b

L~

131.2

131.1

OBn

131.3

F I G U R E 1.131

O II R--O--CH~-- P(C6Hs)2

--OH 2 I o

_c,_ R = OH3,

LO OH3 LoXcH3 , H3c

132.1

F I G U R E 1.132

CH 3 CH 3

H-,.c~,O L o 0X c H 3OH3 + CH3SiCH2SO2C6H5 133.1

133.2

E:4 39 SO2C6H5 H-.,c~O

~

LO

CH3

onlyE /

?o LoXC: 133.3

133.1

(C2H50)2P(O)CH2SO2C6H5 133.5

F I G U R E 1.133

~ O SO206H5 OH3

LoXc m 133.4

1.2.

] 75

BUILDUPOF SUGARSWITH ASCENDINGSYNTHESIS

the ( E ) - o l e f i n (133.4) is p r o d u c e d exclusively w h e n the t r a n s f o r m a t i o n is p e r f o r m e d 397 with d i e t h y l ( p h e n y l s u l f o n y l ) m e t h a n e p h o s p h o n a t e (133.5).

(Z,E)-(4'S)-2-(2,2'-Dimethyl-l',3'-dioxolan-4'-yl)-vinyl phenylsulfone (133.3 and133.4) 396 A solution of phenyltrimethylsilylsulfone (133.2,1 mmol) in dimethoxyethane (5 ml) is cooled to -78~ and an equimolar amount of n-butyllitium is added under argon atmosphere. The yellowish solution is kept at -78~ for 20 min, and then a solution of 2,3-O-isopropylidene-D-glyceraldehyde (133.1, 1 mmol) in a small volume of dimethoxyethane is added dropwise. The temperature is allowed to raise to room temperature, aqueous ammonium chloride is added, and the organic layer is separated, dried and concentrated. Column chromatography of the residue gives 72% of an (Z/E) mixture (133.3 and 133.4) of the title product. (E)-(4'S)-(2,2'-Dimethyl-l',3'-dioxolan-4'-yl)-vinyl phenylsulfone (133.4) 397 To a mixture of diethyl(phenylsulfonyl)methylphosphonate (133.5,10.2 g, 35 mmol) in THF (50 ml), potassium tert-butoxide (3.7 g, 33 mmol) is added at 0~ and the mixture is cooled to -78~ and then treated with a dropwise addition of a solution of 2,3-O-isopropylidene-D-glyceraldehyde (133.1, 4 g, 30 mmol) in 15 ml of THF. After stirring for 2 h, the reaction is quenched with aqueous NaHSO4 and the mixture is allowed to warm to room temperature. It is then extracetd with ether, and the organic layer is separated, washed with water and aqueous NazCO3, dried over MgSO4, and concentrated. Column chromatography of the residue yields 4.05 g of the pure (E)-olefin 133.4, [a]~ +14.08 (c = 1.15 in chloroform). By e m p l o y i n g 1,2-O-isopropylidene-3-O-benzyl-c~-D-ribofuranos-l,4ulose (134.1) and one e q u i v a l e n t (1 eq) of lithium chloride, the s a m e p r o c e d u r e (Fig. 1.134) gave 397 63% of 3-O-benzyl-5,6-dideoxy-(E)-5,6didehydro-l,2-O-isopropylidene-6-phenylsulfonyl-a-D-glucofuranose {134.2, m.p. 110-111~ [c~]~ +18 (c = 1 in chloroform)}. Starting f r o m aldehydes and d i a l k o x y p h o s p h o r y l methylsulfones, the H o r n e r - W a d s w o r t h - E m m o n s carbonyl olefination allows the p r e p a r a t i o n of vinylsulfones that can be t r a n s f o r m e d , in a s u b s e q u e n t Michael addition, into glycosylmethylsulfones. T h e first r e l a t e d w o r k published r e p o r t e d 39s the t r a n s f o r m a t i o n of the 4-deoxy-D-xylo-hexose derivatives (135.1) with diethyl ( p h e n y l s u l f o n y l ) m e t h y l p h o s p h o n a t e (135.2) to result in the C-glycosylsulfones 135.3 as shown in Figure 1.135. By t r e a t m e n t with s o d i u m hydride, the c~,/3-sulfone mixture 135.3 can be c o n v e r t e d into the fl-isomer, and f u r t h e r studies 399 have r e v e a l e d that

SO206H5 L~

CHO

O@CH 3 OH3 134.1

IPEA, LiCl 63% FIGURE 1.134

;

nO. o ;@OH 134.2

OH 3

3

176

I ASCENDINGSYNTHESIS OF MONOSACCHARIDES

O 3

O OH

+

(C2HsO)2P(O)CH2SO2C6H5

~

3

t

I

OCH3 135.1

CH2SO2C6H5 OCH3

135.2

135.3

FIGURE 1.135

this strategy can be employed for the chain extension of additional sugars, such as D-glucose, 2-deoxy-D-glucose and 4,6-O-ethylidene-D-glucose. 3-(Diethylphosphono)acrolein diethyl dithioacetal (136.2) represents a specific reagent among the PO-activated phosphorous compounds, as it is suitable for chain extension by three carbon atoms. For example, Figure 1.136 shows that the product of the olefination 4~176 with 136.2 is the C8-ketene dithioacetal 136.3 when the starting sugar is 2,3 : 4,5-di-O-isopropylidenealdehydo-D-arabinose (136.1). A modern preparative synthesis of 2-deoxy-D-ribose, worked out by Rapoport, 4~ is based on the convenient chain extension (Fig. 1.137) of 2,4-O-ethylidene-D-erythrose (137.1), available by the oxidation of 4,6-0ethylidene-D-glucose, with the anion of (dimethylphosphoryl)methyl phenylsulfone (137.2). The resulting (pent-2-en-l-yl) phenyl sulfoxide 137.3 can be then readily converted into 2-deoxy-D-ribose. (E/Z)-(3R,4R)-3,5-(Ethylidenedioxy)pent-2-en-l-yl phenyl sulfoxide (137.3) 4~ To a solution of (dimethylphosphoryl)methyl phenylsulfoxide (2.48 g, 10 mmol) in dry THF (20 ml), 11 ml of a n-hexane solution of butyllithium is added dropwise at -70~ over a period of 3 h. Stirring is continued at -70~ for an additional 4 h, and then a solution of 2,4-O-ethylidene-D-erythrose (137.1, 2.0 g, 10 mmol) in dry THF (25 ml) is added and the stirred mixture is allowed to warm to room temperature. Stirring is continued overnight, the solvent is distilled off, and the residue is mixed with water (25 ml) and extracted with 3 • 15 ml of chloroform. The combined organic solution is washed with water (15 ml), dried over MgSO4, and concentrated to give 75-87% of the isomeric mixture 137.3.

H.~c~O ~~CH3 O==::1 "CH3

(C2HsS)2CH" ~ I

p(O)(OC2Hs)2

136.2

mcXo--I

H3C

-'~

H SC2H5 H ~;C......C'C ~ 802H5 ~, H 3 0OH %3O O ~ o C H

OV~

_O---I

136.1

H3c~CH3

136.3

FIGURE 1.136

177

1.2. REFERENCES

~ O ...S(~)/C6H5

I

H .., c~.O

]

O

H

+

HC~.-C"k H

(9

(CH30)2P(O)CHS(O)C6H5 o

O . CH3

L__ O

137.1

137.2 FIGURE

REFERENCES

TO

SECTION

.

OH 3

137.3 1.137

1.2.6

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I ~6

I


327. M. N. Mirzayanova, L. N. Davidova, and G. I. Samokhvalov, Zh. Obshch. Khim. 40, 693 (1970). 328. P. S. Liu, R. S. Rogers, M. S. Kong, and P. S. Sunkara, Tetrahedron Lett. 32, 5853 (1991). 329. O. Duclos, A. Dur6ault, and J. C. D6pezay, Tetrahedron Lett. 33, 1059 (1992). 330. K. C. Nicolaou, D. G. McGarry, P. K. Somers, B. H. Kim, W. W. Ogilvie, G. Yiannikouros, C. V. C. Prasad, C. A. Veale, and R. R. Hark, J. Am. Chem. Soc. 112, 6263 (1990). 331. C. R. Bertozzi, D. G. Cook, W. R. Kobertz, F. Gonzalez-Scarano, and M. D. Bednarski, J. Am. Chem. Soc. 114, 10639 (1992). 332. T. K. M. Shing, Z.-H. Zhou, and T. C. W. Mak, J. Chem. Soc., Perkin Trans. 1, p. 1907 (1992). 333. K. R. C. Prakash and S. P. Rao, Tetrahedron 49, 1505 (1993). 334. J.-M. Beau, P. Sinay, J. P. Kamerling, and J. F. G. Vliegenthart, Carbohydr. Res. 67, 65 (1978). 335. O. R. Martin, F. E. Khamis, and S. P. Rao, Tetrahedron Lett. 30, 6143 (1989). 336. J. C. Barnes, J. S. Brimacombe, and G. McDonald, J. Chem. Soc., Perkin Trans. l, p. 1483 (1989). 337. J. S. Brimacombe and A. K. M. S. Kabir, Carbohydr. Res. 152, 335 (1986). 338. T. L. Cupps, D. S. Wise, and L. B. Townsend, Carbohydr. Res. 115, 59 (1983). 339. O. R. Martin and W. A. Szarek, Carbohydr. Res. 230, 195 (1984). 340. A. G. Tolstikov, O. F. Prokopenko, L. M. Khalilov, V. N. Odinokov, and G. A. Tolstikov, Zh. Org. Khim. 27, 788 (1991). 341. G. H. Jones, E. K. Hamamura, and J. G. Moffatt, Tetrahedron Lett. 9, 5731 (1986); H. P. Albrecht, G. H. Jones, and J. G. Moffatt, J. Am. Chem. Soc. 92, 5511 (1971). 342. H. Paulsen, W. Bartsch, and J. Thiem, Chem. Ber. 104, 2545 (1971). 343. F. M. Unger, D. Stix, E. M/3derndorfer, and F. Hammerschmid, Carbohydr. Res. 67, 349 (1978). 344. R. W. McClard, Tetrahedron Lett. 24, 2631 (1983). 345. B. E. Maryanoff, S. O. Nortey, R. R. Inners, S. A. Campbell, A. B. Reitz, and D. Liotta, Carbohydr. Res. 171, 259 (1987). 346. W. S. Wadshworth, Org. React. (N. Y.) 25, 73 (1977). 347. Houben-Weyl, Methoden der Organischen Chemie, Vol. 5/lb, pp. 395, 895,1972; Vol. 12/1, pp. 262, 523; Vol. E/2, p. 300, 1982; Vol E/11, pp. 779, 1235, 1983. 348. H. Pommer and P. C. Thieme, Top. Curr. Chem. 109, 165 (1983). 349. N. Minami, S. S. Ko, and Y. Kishi, J. Am. Chem. Soc. 104, 1109 (1982). 350. B. M. Trost, S. Mignani, and T. N. Nanniga, J. Am. Chem. Soc. 110, 1602 (1988). 351. A. Bernardi, S. Cardani, C. Scolastico, and R. Villa, Tetrahedron 44, 491 (1988). 352. P. P. Waanders, L. Thijs, and B. Zwanenburg, Tetrahedron Lett. 28, 2409 (1987). 353. A. Krief, W. Dumont, and P. Pasau, Tetrahedron Lett. 29, 1079 (1988). 354. N. Ikemoto and S. L. Schreiber, J. Am. Chem. Soc. 112, 9657 (1990); S. Saito, Y. Morikawa, and T. Moriwake, J. Org. Chem. 55, 5424 (1990). 355. H. Iida, N. Yamazaki, and C. Kibayashi, J. Org. Chem. 52, 3337 (1987). 356. S. Ohira, S. Ishi, K. Shinohara, and H. Nozaki, Tetrahedron Lett. 31, 1037 (1990). 357. R. Plantier-Royon, and D. Anker, J. Carbohydr. Chem. 10, 239 (1991). 358. T. Katsuki, A. W. M. Lee, P. Ma, V. S. Martin, S. Masamune, K. B. Sharpless, D. Tuddenham, and F. J. Walker, J. Org. Chem. 47, 1378 (1982). 359. S. F. Martin, D. W. Dean, and A. S. Wagman, Tetrahedron Lett. 33, 1839 (1992). 360. H. Maehr, A. Perrotta, and J. Smallheer, J. Org. Chem. 53, 832 (1988). 361. A. B. Reitz, A. D. Jordan, Jr., and B. E. Maryanoff, J. Org. Chem. 52, 4800 (1987). 362. N. Katagiri, K. Takashima, T. Haneda, and T. Kato, J. Chem. Soc., Perkin Trans. 1, p. 553 (1984). 363. Yu. A. Zhdanov, L. A. Uslova and L. M. Maximushkina, Zh. Obshch. Khim. 53 484 (1983).

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364. I. W. Lawston and T. D. Inch, J. Chem. Soc., Perkin Trans. 1, p. 2629 (1983). 365. A. Lieberknecht, J. Schmidt, and J. J. Stezowski, Tetrahedron Lett. 32, 2113 (1991). 366. U. Schmidt, A. Lieberknecht, U. Kazmaier, H. Griesser, G. Jung, and J. Metzger, Synthesis, p. 49 (1991). 367. A. Saroli and A. Doutheau, Tetrahedron Lett. 28, 5501 (1987). 368. S. Knapp and P. J. Kukkola, J. Org. Chem. 55, 1632 (1990). 369. J. W. Krajewski, P. Gluzinski, Z. Urbanczyk-Lipkowska, J. Ramza, and A. Zamojski, Carbohydr. Res. 200, 1 (1990). 370. J. Ramza and A. Zamojski, Carbohydr. Res. 228, 205 (1992). 371. G. Estenne, A. Saroli, and A. Doutheau, J. Carbohydr. Chem. 10, 181 (1991). 372. P. Allevi, P. Ciuffreda, D. Colombo, G. Speranza, and P. Manitto, J. Chem. Soc., Perkin Trans. 1, p. 1281 (1989). 373. D. Monti, P. Grammatica, G. Speranza, and P. Manitto, Tetrahedron Lett. 28, 5047 (1987). 374. D.-P. Neff, Y. Chen, and P. Vogel, Helv. Chim. Acta 74, 508 (1991). 375. R. J. Ferrier and P. Prasit, J. Chem. Soc., Perkin Trans. 1, p. 1645 (1983). 376. H. Itoh, T. Kaneko, K. Tanam, and K. Yoda, Bull Chem. Soc. Jpn. 61, 3356 (1988); H. Itoh, Noguchi Kenkyusho Jiho, p. 37 (1988); Chem. Abstr. 111, 154236o (1989). 377. S.-K. Kang, H.-S. Cho, H.-S. Sim, and B.-K- Kim, J. Carbohydr. Chem. 11, 807 (1992). 378. J. Ramza and A. Zamojski, Tetrahedron 48, 6123 (1992). 379. F. Paquet and P. Sinay, Tetrahedron Lett. 25. 3071 (1984). 380. K. Narkunan and M. Nararajan, J. Org. Chem. 59, 6386 (1994). 381. S. Jarosz, Tetrahedron Lett. 35, 7655 (,1994). 382. G. W. J. Fleet and T. K. M. Shing, J. Chem. Soc., Chem. Commun., p. 849 (1983). 383. S. Mirza and A. Vasella, Helv. Chim. Acta 67, 1562 (1984). 384. M.-I- Lim and V. E. Marquez, Tetrahedron Lett. 24, 4051 (1983). 385. H.-J. Altenbach, W. Holzapfel, G. Smerat, and S. H. Finkler, Tetrahedron Lett. 26, 6329 (1985). 386. V. E. Marquez, M. I. Lim, C. K.-H. Tseng, A. Markovac, M. A. Priest, M. S. Khan, and B. Kaskar, J. Org. Chem. 53, 5709 (1988). 387. R. Huber and A. Vasella, Tetrahedron 46, 33 (1990). 388. G. W. J. Fleet, T. K. M. Shing, and S. M. Warr, J. Chem. Soc., Perkin Trans. 1, p. 905 (1984). 389. S. Mirza and J. Harvey, Tetrahedron Lett. 32, 4111 (1991). 390. H. Paulsen and W. von Deyn, Justus Liebigs Ann. Chem., p. 125 (1987). 391. H. Paulsen, W. Bartsch, and J. Thiem, Chem. Ber. 104, 2545 (1971). 392. G. M. Blackburn and A Rashid, J. Chem. Soc., Chem. Commun., p. 40 (1989). 393. H. Paulsen and W. Bartsch, Chem. Ber. 108, 1745 (1975). 394. K. Suzuki and T. Mukaiyama, Chem. Lett., p. 683 (1982). 395. F. Nicotra, L. Panza, F. Ronchetti, G. Russo, and L. Thoma, J. Chem. Soc., Perkin Trans. 1, p. 1319 (1987). 396. D. Craig, S. V. Ley, N. S. Simpkins, G. H. Whitham, and M. J. Prior, J. Chem. Soc., Perkin Trans. 1, p. 1949 (1985). 397. B. M. Trost, P. Seoane, S. Mignani, and M. Acemoglu, J. Am. Chem. Soc. 111, 7487 (1989). 398. N. J. Barnes, A. H. Davidson, L. R. Hughes, and G. Procter, J. Chem., Soc. Chem. Commun., p. 1292 (1985). 399. A. H. Davidson, L. R. Hughes, S. S. Qureshi, and B. Wright, Tetrahedron Lett. 29, 693 (1988). 400. G. Just, P. Potvin, and G. H. Hakimelahi, Can. J. Chem. 58, 2780 (1980). 401. J. Hauske and H. Rapoport, J. Org. Chem. 44, 2472 (1979).

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1.2.7. Miscellaneous Methods for Extension of the Monosaccharide Chain

The conventional and most widely known methodologies for extension of the carbohydrate chain have been collected and described in the previous sections. The present section is aimed at discussing a variety of methods that cannot be classified into the former, larger groups of procedures, and that are now a bit outdated but still applicable in special cases, as well as many of those--although introducedmbut have not been extensively employed in the carbohydrate field. 1.2.7.1. Chain Extension by Addition of Organometallic Compounds to an Aldehyde or Lactol Function of Saccharides

1.2.7.1.1. Extension of the Sugar Chain by the Addition of Grignard Reagents to aldehydo-Sugars Starting from simple chiral aldehydes, such as glyceraldehyde, lactaldehyde or tartraldehyde, modern carbohydrate chemistry extensively employs acyclic stereoselective methods 1for the construction of complex saccharides based on related procedures. The addition of organometallic reagents to aldehydo-sugars is a crucial step in the syntheses of higher-carbon carbohydrates and for the preparation of the chiral structural units of polyether antibiotics and other agents. Known models of asymmetric induction (chelation or nonchelation control) can be used to predict the diastereofacial selectivity of such reactions in a variety of saccharide substrates. The cyclic chelate model was proposed by Wolfrom and Hanessian 2 to account for the diastereofacial selectivity of Grignard reagents to 1,2-O-isopropylidene3- O-be nzyl- I>xyl o furan os- 1,4-ul ose. These stereochemical studies have been also carried out 3 with the simplest open-chain saccharide: 2,3-O-isopropylidene-D-glyceraldehyde. The reactions of this aldehyde with a large variety of carbanions (e.g., with alkyl and arylmagnesium halides, alkyllithium reagents, alkyltitanium isopropoxides) have been accomplished, and the stereochemical outcome of these transformations, including the influenece of various factors, have been determined by means of comprehensive analytic methods (HPLC, GC and NMR). The following example (Fig. 1.138) shows the chain extension of 2,3O-isopropylidene-D-glyceraldehyde (138.1) with diallyl zinc to give rise 4 to (2R,3S)- and (2R,3R)-l,2-O-isopropylidene-5-hexen-l,2,3-triol (138.2 and 138.3, respectively), and similar reactions of the sugar 138.1 with ethinyl and vinylmagnesium bromide have also been reported. 5 Preparation of (2R,3S)- and (2R,3R)-l,2-O-isopropylidene-5-hexen-l,2,3-triol (138.2 and 138.3) 4 To a solution of allylmagnesium chloride (0.52 mol) in THF (700 ml), zinc chloride (36.2 g, 0.266 mol) is added in small portions at 0~ and the resulting gray suspension is stirred for 30 min at room temperature and cooled

189


H...c~.O

OH2-- CH- CH2MgCI

LO CH3 oXcH3

c

ZnCI2

---]"OH2 HO~ O

L-OH3 LoXoH~

138.1

CH..~ OH O

+

k- OH3 LoXcH3

138.2

138.3

FIGURE 1.138

to -10~ Then a solution of 2,3-O-isopropylidene-D-glyceraldehyde (138.1, 28.63 g, 0.22 mmol) in THF (150 ml) is added dropwise and stirring is continued at 20~ for 2h. After addition of aqueous ammonium chloride and conventional workup 31.11 g (82%) of an 85" 15 mixture of 138.2 and 138.3 is obtained. The chain extension of numerous monosaccharide derivatives, including sugars with free anomeric hydroxyl group and alduloses, with different Grignard reagents have been carried out, and these studies were also aimed at investigating the influence of various factors (complexation, solventeffects, anomeric configuration, substitution pattern, etc.) on such of reactions. However, it is still difficult to predict a general outcome of the process in many cases. Nevertheless, in the light of the following results and examples, published in three detailed studies, 6-8 considerably useful (and somewhat generalizable) insight on the stereochemical outcome of the Grignard chain extensions can be gained. As reported by Singh et al., 6 the reaction of 2,3-O-isopropylidene-Derythrofuranose (139.1), 2,3-O-isopropylidene-D-ribofuranose (139.2), 2,3:5,6-di-O-isopropylidene-D-allofuranose (139.3), 2,3:5,6-di-O-isopropylidene-D-mannofuranose (139.4) and 2,3-O-isopropylidene-D-lyxofuranose (139.5) with different Grignard reagents (Fig. 1.139 and Table 1.25) gives

w•/O ..~

OH R'MgX

6b

.~

•

•

H3C CH3

~--~o

H~c

0

0

139.1

0

139.2

*

•

H3C OH3

anti (erythro)

syn (threo)

o

0

H3cXcH 3

H

/ \ 6b

H3C CH3

H

H3cXcH3

R__OH

/ \ /R 6b

O O H3cXcH3 139.3

FIGURE 1.139

H~cXo,

RO~ jO I

0 "~ BnO~NHBn

r

OH2 F ~ 28

+

MgBr

THF, 25~

OBn

CH2 30 BnO ~_OB n

L~ 88% d.e. F I G U R E 1.143b

is passed through the mixture during the addition and the next 60 min. After cooling to 0~ a solution of methyl 2,3-O-isopropylidene-~-D-ribo-pentodialdo-l,4furanoside (144.1, 1.3 g) in THF (10 ml) is added over a 30-min period. Acetylene is passed through the solution throughout the addition and for a further 3 h. Then the mixture is allowed to warm to room temperature, stirred overnight, and concentrated. A solution of the residue in ether (50 ml) is washed with saturated aqueous ammonium chloride (3 • 50 ml) at 0~ and water (50 ml), dried over MgSO4, and concentrated. The resulting crystalline mixture of 144.2 and 144.3 (1.4 g) is fractionated by preparative gas-liquid chromatography (GLC) (column: 10% PEG-4000 on Chromosorb WAW, 190~ to furnish 48% of pure 144.2, as white needles, m.p. 93-94~ [a]~ -96 (c = 0.5 in chloroform), T = 1.22 (cf. 1.00 for 144.3)" and 144.3 (52%), m.p. 63-64~ [c~]~ -13 (c = 0.5 in chloroform). An additional, very useful procedure has been described by Czernecki et al. 39 u t i l i z i n g t r i m e t h y s i l y l a c e t y l e n e f o r a n a l o g o u s c h a i n e x t e n s i o n s (Fig. 1.144).

Methyl 2,3,4-tri-O-benzyl-7,8-dideoxy-L-glycero- and D-glycero-D-gluco-oct-7ynopyranoside (144.7 and 144.8) 39 The reaction is to be carried out under argon. Two batches of anhydrous magnesium bromide (24 mmol each) are prepared from magnesium turnings (0.6 g, 24 mmol) and 1,2-dibromoethane (2.1 ml, 24 mmol) in ether (15 ml) at room temperature. In a separate flask, (trimethylsilyl)acetylene (1.92 ml, 13.6 mmol) is added dropwise to a cooled (-5~ solution of n-butyllithium (7.8 ml of a 1.6 M solution in hexane diluted with 15 ml of ether). After stirring for 15 min, this mixture is added to one batch of freshly prepared anhydrous MgBr2. The resulting white suspension is cooled to -30~ The second batch of MgBr2 (24 mmol) is added to the dialdosugar 144.4 (1.43 g, 3.09 mmol) dissolved in ether (70 ml), and the preceding suspension is added to this mixture at -30~ The mixture is allowed to attain room temperature before careful hydrolysis with saturated aqueous ammonium chloride (50 ml). Following decantation, the aqueous layer is extracted with ether (2 • 50 ml) and the combined organic layer is washed

196

I ASCENDING SYNTHESIS OF MONOSACCHARIDES Refs.

H ~.C~,.O ---O .OH 3 O~CH3

y (CH3) C Iil C

HC~CMgBr H3C--C_:CMgBr

OXCH3

CliO

OCH., HC~CMgBr

H

H

III C

III C

HOq

OCH3

~--OH OCH3

O O H3CXCH3

0 0 H3C~'CH3

0 0 H3CXCH3

144.2

144.1

144.3 H III C

CHO

OH

HC~CMgBr HC-I 3 CH3

O

O._.~.-CH3

CH3

O

NBn2

38

O O

HC 3 OH3 X-~

O---~ CH3 CH3 OH /~'B'IBn2

HC=CMgBr O _O .>20 TiCI4 : ~ ~O H + products

113

. O4_oX; l-OAt

y

Ac,O ,J----o

l--oAc

?

o J---o

OAc

OAc I---OC8H18

OAc

I---OAc

Ao,OJ___o

o

)

r---OAc o

OAc 2, %o~, OAc ~ \o~c I

,08

I%._=

OAc I--OC8H18

OAc

104

R 4 0 I____00-------q

R40 ,L__._O o

o

~/o~ g R~O)---o N d

/

[(/OR3

\

OR2

OR

--

R 2 = R 3 = R 4 = Bz

R 2 = R 3 = R 4 = Ac

R 2 = R 3 = R 4 = Bn

major product, 174.3, can be isolated as a white solid (193 mg, 45%), that gives long needles on recrystallization from methanol, m.p. 79-80~ [o~]2D 8 +61.4 (C = 1.7 in dichloromethane).

C-Glycosyl-allenes, containing a cumulative double-bond system, c a n also be synthesized 115 ,124 -127 according to the procedure discussed above, by the reaction of 1-O-acyl aldoses or alkyl glycosides with propargyltri-

0 ~?Ac ~ + ~,,,,,,,.,fSi(CH3) 3 BF3"(C2H5)20 ~. AcO " 20~ \ OAc 173.1

FIGURE 1.173

+ \\O

o(~

L-erythro

D-threo

173.2

173.3


+n o c

OBn o

BnO "

. ~Si(CH3)3,

CO--@-NO

BF3"(C2H5)20 0oC

2

223

F~176 BnO"

~Bn%

OBn

174.2

4 "t 4 4 | 4 -lr~ |

174.3

FIGURE 1.174

methylsilane (see Fig. 1.175). The products (175.1) are used primarily for further conversion 115,127 of the C-glycosyl allenic unit into a --CHaCHO moiety. With open-chain saccharides, the present chain extension is often accompanied by an additional reaction. Thus, when the 2,3-O-isopropylidene derivatives of aldehydo-aldoses (176.1) are treated with allylsilanes, vinylethers, or vinylsulfides (176.2) in the presence of boron trifluoride (Fig. 1.176), tetrahydrofuranes (such as 176.3) may be produced, presumably resulting from intramolecular cyclization accompanied by migration of the isopropylidene g r o u p 117'128-132 (seealso Fig. 1.170). Organotin compounds have also emerged as important reagents for the chain extension of saccharides. Allytri-(n-butyl)stannane is used, in the presence of lithium perchlorate, for the chain extension of aldehydo -~ sugars into unsaturated higher-carbon saccharides, ~33 such as the methyl 6-heptenosides shown in Figure 1.177. Addition of tributyltin hydride to an acetylenic bond of a sugar results in an organotin olefin that, on treatment with n-butyllithium and subsequent reaction with an aldehydo-sugar, can be converted into most valuable chainextended products, such as those available TM from 6-O-benzyl-7,8-dideoxy, 1,2:3,4-di-O-isopropylidene-L-glycero-c~-o-galacto-oct-7-ynopyranose (178.1) by the reaction sequence shown in Figure 1.178. The ratio of the produced L-ido (178.2) and D-gluco (178.3) diastereoisomers can be relatively easily controlled TM by the reaction temperature: at -78~ this ratio is 3:1 but it is 3"2 at 0~ The chain-extension principle described in the preceding paragraphs has been successfully applied by Jarosz and Fraser-Reid 135-137for the synthesis of higher-carbon sugars (Fig. 1.179). Starting from 6,7-dideoxy1,2:3,4-di-O-isopropylidene-c~-D-galacto-hept-6-ynopyranose (179.1), the

O~o " OH3 OBn

~

\Si(CH~3 30 h, 0 ~

,

oa I ~ OBn

,s cH33 9

175.1

FIGURE 1.175

OBn

224

H~C


O

_CliO

BF3"Et20 +

.3c

~"XR'

176.1

9.

HJ

176.2

/~

,BEg (~)

~

-BF 3

XR'= CH2Si(CH3) 3, O, S

.o

XR'

H3co OH3

176.3

F I G U R E 1.176

reaction could be designed and executed so that the anion of 179.1 gave a 33:67 mixture of the propargyl alcohols 179.3 and 179.4 with the aldehydosugar 179.2. Subsequent hydrogenolysis of the product mixture then led to the cis/trans alcohols 179.5. When the 6-ynopyranose was first treated with tributyltin hydride (179.1 --+ 179.6) and then coupled with the aldehydosugar 179.2 (with n-butyllithium), the epimeric trans-dodecenoses (179.7 and 179.8) were produced in a ratio of 72:28. Saccharide derivatives with a C--Sn bonding are also available, 138-144 and these are susceptible to chain extension into higher-carbon sugars following transformation into the lithioorganic analogs. Thus, configurationally stable 2-deoxy-/3- and -c~-D-hexopyranosyl lithium compounds can be prepared and reacted with electrophilic compounds with retention of

C~O~

O

OCH3 +

O

H3C.~CH3

~k

.,~

_ LiC'O4

Sn(n-C4H9)3

.'~ HO

CH3

Et20

O

+

H

O

O

H3CXCH3

O

H3CXCH3

25

F I G U R E I. 177

OCH3

91

1.2. BUILDUP OF SUGARS "WITH ASCENDING SYNTHESIS H

SnE}u3

III C

n Bn

Bu3SnH O H3C CH 3

225

O---~ OH3 OH3

0

/~

+

0

0

o

HC 3 CH3

O--~CH3

H3c

CH3

CH3 (Z)-

178.1

CH 3 and

(E)-

6-O-benzyl-7,8-dideoxy-1,2:3,4-di-O-isopropylidene-

L-glycero-o~-D-galacto-oct-7-enopyranose 1, BuLi CHO n

CH a

H ,, OH

OH ,,~H

o4-o. CH 3

CHa

178.2

178.3

3-O-benzyl-6-C[(E)-6-O-benzyl-7-deoxy-1,2:3,4-di-O-

3-O-benzyl-6-C[(E)-6-O-benzyl-7-deoxy- 1,2:3,4-di-O-

isopropylidene-L-glycero-o~-D-galacto-heptopyranose-7-

isopropylidene-L-glycero-o~-D-galacto-heptopyranose-7-

[(x] ~0 = -86 (c = 0.7, EtOAc)

[(~]20 = -34 (c = 1.3, EtOAc)

ilidene]-6-deoxy-1,2-O-isopropylidene-13-L-idofuranose

ilidene]-6-deoxy- 1,2-O-isopropylidene-(x-D-glucofura nose

F I G U R E I.I 78

the configuration. 138 The results of the studies of B e a u 139 o n the chain extension of glycosylstannanes with various anhydro compounds are summarized in Table 1.29. The preparation of the chiral polyhydroxyalkyl pyrans and dihydropyrans was carried out in the presence (procedure A) or in the absence (procedure B) of 2-thienyl-cyanocuprate under boron trifluoride catalysis. In further studies in this field, 1-tributylstannyl-D-glucals were coupled efficiently to different organic halides in the presence of Pd(0) catalyst, and this mild process is very useful for the preparation 142 of 1-C-aryl-Dglucals. Stereospecific Pd/Cu cocatalyzed cross-couplings of tributylstannyl glucopyranosides with thiono- and thiolochloroformates afford good yields

226

i

ASCENDING

SYNTHESIS OF N O N O S A C C H A R I D E S

c~C~~,;o oJ--o ~~ R1

H CHO

III C

0 )----0 3 CH 3

BuLi

+

CH3

O__~___CH 3

.

'

3 CH 3

O ~__.CH 3

CH 3

CH3

OH 3

179.1

179.3 R 1 = OH; R 2 = H

179.2

179.4 R 1 = H; R 2 = OH ~ H2/Pd-BaSO 4 H3C H3C ~ - - O

O~]Nx

Bu3SnH,

~,

xylene, A

CHa

c~ ~ J - - - C H R 1

-o.__7,~

~.

R~

9

O

.

o ~

O@CH 179.5

SnBu 3

CH~ H3C-~.~

\/~o

BuLi O

3

CH3

R1 ____.~,,, R 2

//---~-

~ o

O

o~

CHO H3C

CH 3

+

o

H3C__~O~-

OH 3

,o5>c.,

/ H3C

fo

O~CHa OH 3

CH3 179.6

179.2

179.7 R 1 = OH; R 2 = H 179.8 R 1 = H; R 2 = O H

F I G U R E 1.179

of C-glucosylthiocarboxylates. 14~C-Glycosylcarboxylates (2,6-anhydroheptonic acids) are obtained by conversion of the stannylated glycopyranosides into the lithioderivatives, followed by carboxylation with carbon dioxide. According to the procedure of Fuchs, 141 related coupling reactions for the chain-extension of anomeric stannanes (available as described by Sinay 138) with enones can be executed via glycosyl copper reagents as shown in Figure 1.180. 1-(3',4',6'- Tri-O-benzyl-2'-deoxy-~-D-glucopyranosyl)butan-3-one

(180.2) 141

A solution of 316 mg (0.446 mmol) of 1-tributylstannyl-3,4,6-tri-O-benzyl-~-D-arabino-hexopyranoside (180.1) 138 in 2.2 ml of dry THF at -78~ is treated with 0.18 ml (2.49 M, 0.456 mmol) of n-butyllithium in hexane followed by stirring at this temperature for 10 min. The yellow solution is transferred via a cooled cannula to a solution of 101 mg (0.491 mmol) of copper(I)bromide-dimethyl sulfide in 0.5 ml of diisopropyl sulfide and 0.6 ml of THF at -78~ pretreated with 1 drop


22"/

(---10/xl) of 2.0 M isopropylmagnesium chloride in THF as described previously, followed by stirring at -78~ for 15 min. To the brown solution is added 26 mg (31/xl, 0.372 mmol) of neat methyl vinyl ketone and then 70 mg (60/xl, 0.491 mmol) of boron trifluoride etherate. The reaction mixture is stirred at -78~ for 10 min, followed by warming to -50~ for 5 min and to 0~ for 2 min. The solution is then added to 50 ml of 1:1 NH3-NH4C1solution, diluted with dichloromethane (30 ml), and stirring is continued at ambient temperature for 30 min. The aqueous layer is extracted with dichloromethane, the combined organic layer is dried (Na2SO4) and concentrated in vacuo to a colorless syrup, which is submitted to column chromatography on silicagel [12 g, 200-400 mesh, eluant: 100 ml of 10% (v/v) and then 16% (v/v) ethyl acetate in hexane] to afford 100 mg (55%) of the C-glycosidic compound 180.2, as a colorless syrup. The stereoselective addition of allylboron reagents to dialkoxyaldehydes leads to 1-C-(prop-2-enyl)dialkoxyalkane derivatives, of which the C5 and C6 representatives are extremely useful 1'3'145 for the synthesis of oJ-deoxymonosaccharides. This procedure can be well utilized for the preparation of certain deoxysugars as shown by the example of 2-deoxy-D-erythropentose (Fig. 1.181). T r e a t m e n t of 2,3-O-isopropylidene-D-glyceraldehyde (181.1) with 2-allyl-4,4,5,5-tetramethyl-l,3,2-dioxaborolane (181.2) gives rise 146 to an epimeric mixture (181.3) of 2,3-O-isopropylidene-l-C-(prop-2enyl)-D-threo- and D-erythro-glycerol, from which the desired deoxypentose can be prepared. The stereoselectivity of the addition can be influenced 147 by the addition of isopropyl D- or L-tartarate, but chiral boron reagents have also been efficiently employed for this purpose. 148'149The threo/erythro ratio in the product mixture 181.3 is ---15"25, which may slightly change by varying the reaction conditions (solvent, temperature), and almost the same ratio of the products (181.5) is observed in a similar addition 15~ of the boron c o m p o u n d 181.2 to 2,3-O-cyclohexylidene-D-glyceraldehyde (181.4). By applying an appropriate borolane reagent (182.1), one can adopt the preceding chain extension principle for the diastereoselective synthesis 151 of the protected D-fUcose derivative 182.2 (Fig. 1.182). (Z)-3,-Methoxymethylallylboronate (183.1), available by the reaction of allylmethoxy methyl ether and FB(OCH3)2, has been coupled with 2,3O-cyclohexylidene-D-glyceraldehyde to obtain 75-80% of the homoallyl alcohol 183.2, the key intermediate in a chiral synthesis 152 of sesbanimide (Fig. 1.183), with a diastereoselectivity higher than 20:1. A n analogous transformation a53 of 4-deoxy-2,3-O-isopropylidene-Lthreose (184.1) with the chiral boronate 184.2 offers one of the synthetic routes (Fig. 1.184) to the homoallyl alcohol 184.3, a target for further conversion into 2,6-dideoxy-D-lyxo-hexose (184.4). A total synthesis of L-oleandrose from two C3 building blocks applies TM the reaction of O-benzyl-L-lactaldehyde (185.1), with 4,5-dimethyl2-[(Z)-3-methoxy-2-propenyl]-l,3,2-dioxaborolane (185.2) to furnish, with 84% yield, a mixture of three C6-triols (Fig. 1.185), from which the desired stereoisomer, (3S,4S,5S)-5-benzyloxy-4-hydroxy-3-methoxy-l-hexene

TABLE 1.29

Chain-Extension of Glycosylstannanes

Epoxide (eq)

Stannanea TBSO

0 -0~n

Procedureb

Yield (%)' isomer ratiod

Product TBSO

B

30 (2:3)

(1 5)

OBn TBDPSO

SnBu,

(1.5)

A

TBDPSO

(1.5)

BnO

BnO A BnO

SnBu,

BnO

OBn

71 (2 : 1)

BnO BnO

OBn

BnO BnO

SnBu,

BnO

?.,,

BnO,,

BnO

(1.5) TBSO TBSO

Lo.. -

TBSO

%,j

B

0

(1 .O)

'Prepared according to the literature cited in Lesimple et a1.13' b~oiprocedure~ A and B, see text. 'Isolated yields are given. d ~ e d u c e dfrom 'H-n.m.r. and isolated yields. eYield obtained using procedure A. Abbreviafions: TBS-tert-butyldimethylsilyl; TBDPS-tert-butyldiphenylsilyl.

A $

TBSO

,\OBn

HO'"

OBn

80

230

~ ASCENDING SYNTHESIS OF MONOSACCHARIDES R

O

1) R ~ R BnOCH2 O BnO~/-~-\ fX

"1"

X=Li

O~

CH2CI2, 93%

H~C~..O

CH 3 0

v

o,~CH3 _O'~CH3

~

H

OH3 184.4

184.3 FIGURE

(185.3), n e e d e d

I . i 84

f o r t h e n e x t s t e p of t h e s y n t h e t i c p r o c e d u r e ,

could be

readily separated.

Preparation of (3S,4S,5S)-5-benzy loxy-4-hydroxy-3-methoxy-l-hexene (185.3)154 To a cold (-78~ stirred solution of 3-methoxypropane (4.3 g, 60 mmol) in dry THF (40 ml) is added under argon atmosphere, via a syringe, sec-butyllithium (1.1 M in cyclohexane, 54.5 ml, 60 mmol) to produce a cloudy yellow mixture, which is stirred for 15 min before the addition of 4,5-dimethyl-2-fluoro-l,3-dioxa2-boracyclopentane (2.4 M in benzene, 25 ml, 60 mmol), discharging the yellow color. Stirring is continued for 30 min at -78~ and then 3.3 g (20.4 mmol) of (2S)-(phenylmethoxy)propanal (185.1) is added. The solution is allowed to slowly warm to room temperature, and stirring is continued for 7 days. Then addition of 20 ml (3.0 M in acetone) of (EtOH)3N solution produced a white fine precipitate, which, after an additional hour of stirring, is removed by filtration through a pad

H'- C(,'O

BnO--~ CH3 185.1

.~,,,,CH3

+ CH307-~~ B"O ~'O'- ~'CH3

~'~

HO~ BnO OH3 (3R,4S,5S)

185.2 FIGURE

1.185

+

CH30 __~OH BnO OH3

+

(3R,4R,5S)

;o

HO~ BnO OH3

CH3

(3S,4S,5S) 185.3

233

1.2. BUILDUP OF SUGARS WITH ASCENDING SYNTHESIS of Celite. The filtrate is concentrated to a thick syrup that is washed onto the top of a short column of silicagel with dry acetone and allowed to stand for several hours before elution with 55% of ethyl acetate in hexane, gradually increasing the solvent polarity until all the desired triol is collected (as determined by TLC analysis of the eluant). This material is concentrated (11.2 g) and purified by mediumpressure liquid chromatography (MPLC) (linear gradient elution, 5-50% ethyl acetate in hexane), affording 4.1 g (84%) of the desired triol 185.3, [c~]~ +43.13 (neat oil) along with two minor products in a ratio of 8.7:1.2:1.0.

O n t h e basis of m e c h a n i s t i c k n o w l e d g e a n d s t e r e o c h e m i c a l c o n s i d e r a tions, t h e p r e c e d i n g chain e x t e n s i o n of O - b e n z y l - L - l a c t a l d e h y d e can be c a r r i e d o u t so t h a t t h r e e of t h e f o u r 2,6-dideoxy-L-hexose isomers are available. A d d i t i o n of ( Z ) - or ( E ) - 4 , 4 , 5 , 5 - t e t r a - m e t h y l - 2 - [ 3 - ( 2 - t r i m e t h y l s i l y l ) ethoxy-2-propenyl]-l,3,2-dioxaborolane to O-benzyl-L-lactaldehyde leads 155 to t h e 3 , 4 , 5 - t r i h y d r o x y l a t e d h e x - l - e n e s with arabino, xylo, ribo, a n d lyxo configurations. W i t h the ( Z ) - b o r o l a n e (186.1), a 8 2 : 1 8 arabino/ xylo m i x t u r e (186.2 a n d 186.3) is o b t a i n e d , w h e r e a s a 4 : 6 ribo/lyxo (186.5/ 186.6) a s y m m e t r i c i n d u c t i o n is o b s e r v e d with t h e ( E ) - i s o m e r 186.4 (Fig. 1.186). By a p p r o p r i a t e f u n c t i o n a l i z a t i o n , t h r e e of t h e f o u r 3,4,5-trihydroxy1 - h e x e n e s h a v e b e e n c o n v e r t e d into 2,6-dideoxy-L-arabino, L-ribo, and Llyxo-hexose (Fig. 1.186). 155

(2S,3S,4R)- and (2S,3R,4S)-2-Benzyloxy)-4-(tert-butyldimethylsilyl)-5-hexen-3ol (186.5 and 186.6)156 To a solution of the (E)-dioxaborolane 186.4 (15.9 mmol) in petroleum ether (30 ml, b.p. 40-60~ is added (S)-2-benzyloxypropanal (2.23 g, 13.6 mmol). After strirring for 4 days at room temperature, ether (25 ml) is added and the mixture is treated with triethylamine (2.03 g, 13.6 mmol) for 12 h. The precipitate is filtered and washed with ether (3 • 15 ml), and the combined filtrate is concentrated and chromatographed on silicagel (45 g, eluant: dichloromethane) to furnish 4.15 g (94%) of the ribo-alcohol 186.5 containing 4% of the lyxo-isomer 186.6 Analytic samples were obtained by GC (column: SE 30 at 180~

CH3 9 /'~'~ ,o "~CH3 + (CH3)C-SI(CH3)s L--B~o'~-CH3cH 3

~O

TBDMS

~" BnoHO~

TBDMSO( ' + B n O 4 OH

CH3 H.. c~.O

186.1

BnO4 CHa

oOH3

_~ "~-'CH. (CH3)C.Si(CH3)2,,/ ~

~O.~CH3 ~ CH3

CH3

186.2

186.3

L-" arabino"

L-"xylo "

#

TBDMSO

NO BnO--~ CH3

186.4

FIGURE 1.186

TBDMS +

OH

BnO_~ CH3

186.5

186.6

L-"ribo"

L-"lyxo"

234

~ ASCENDING SYNTHESIS OF MONOSACCHARIDES

Asymmetric allyboration 157 of threo-(2R,3S)-4-(tert-butyldiphenylsilyoxy)-2,3-epoxybutanal (187.1) and its erythro-(2S,3S)- isomer (187.2) have been found suitable as the basis for a general procedure (Fig. 1.187) for the synthesis of the 2-deoxyhexose stereoisomers. 158 This new and highly stereoselective approach relies on two asymmetric transformations: (1) the Sharpless asymmetric epoxidation and (2) the asymmetric allylboration reaction, which can presumably be used to achieve diastereofacial selection in the addition of allyl- or 3,-alkoxyalkyl units to epoxyaldehydes. This principle of asymmetric allylboration has also been used for the synthesis of the AB-disaccharide unit of olivomycin A . 159

1.2.7.2. Chain Extension of Pyrrole Derivatives

aldehydo-Sugars with

Thiazole, Furan, and

Retrosynthetic considerations indicate that thiazole, oxazole, and pyrrole metalated at position C-2 correspond to a synthetic equivalent of the formyl anion. Detailed studies have revealed that these equivalents are suitable for the chain extension of alkoxyaldehydes, and that the thiazole compounds 2-1ithiothiazole or 2-trimethylstannylthiazole do not ensure selective reaction and/or are not reactive enough. It has also been shown ~6~ that the newly created chiral center has anti-configuration, according to the Felkin-Anh model of asymmetric induction. As masked aldehydes, the resulting 2-polyhydroxyalkylthiazoles can be readily converted into the next "sugar homolog" in three synthetic steps (formation of quaternary salt, reduction, and subsequent hydrolysis). Then the whole procedure (Fig. 1.188) can be repeated with the product to access the next sugar of the

C02C2H5

I

S"--/=-~

x

L

"" 00202H 5

L..

x

(R, R)

o "CHO

OH

187.1

X, Y = H or OR v/B(RJ2

x

']0

"CHO X = H or OTBDPS

R'O R'O/~'~B(Rc)2

/

X

~

y

r

OH

X, Y = H or OR

187.2

F I G U R E 1.187

~

I::::s;eose [is~

1.2. BUILDUP

OF SUGARS WITH ASCENDING SYNTHESIS

R--(CHOH)E--CHO

S

1, CH31 1, CH2CI2 2, (n-C4H9)4NF

+

235

R--(CHOH)

n+l~s--~

9

2, NaBH4 3, HgCI2

~

R--(CHOH)~--3--CHO

Si(CH3)3

FIGURE 1.188

series, and thus this iterative methodology has allowed the construction of a 2-polyhydroxyalkylthiazole with a 10-carbon skeleton, as the longest. 16~

General procedure for the addition of 2-trimethylsilylthiazole to aldehydes (see Fig. 1.188) 16~ A mixture of the aldehydo-sugar (5 mmol) and 2-trimethylsilylthiazole 161 (1.17 g, 7.5 mmol) in dry dichloromethane (25 ml) is stirred at 0-20~ for 12 h. The solvent is distilled off, and tetrabutylammonium fluoride (7.5 mmol) dissolved in THF (30 ml) is added to the residue. After 2 h, the solvent is removed under diminished pressure, the residue is taken up with water and extracted with dichloromethane, and the organic layer is dried (Na2SO4). The residue is purified by means of column chromatography (eluant: 7:3 cyclohexane-ethyl acetate). The products 16~ of the addition of 2-trimethylsilylthiazole to aldehydo-sugar derivatives have been collected in Table 1.30. The examples shown in Table 1.30 represent the capacity of the "thiazole method," offering an iterative approach to 1,2-polyols. A fully stereocontrolled chain extension cannot be realized in this way, because of the anti-selectivity of addition of the reagent to the formyl group. However, this disadvantage can be overcome 16e,163 by oxidation of the product 189.1 into the ketone 189.2, which can then be reduced with either K- or LSelectride to the desired isomer 189.3, which is not directly available by the "thiazole method" (Fig. 1.189). An alternative solution is the direct preparation of the 2-thiazolylketone and subsequent reduction (as previously) to the syn-2-thiazolylalcohol. An example of such a methodology 16e,~64 is shown in Figure 1.190. From ethyl (S)-O-(benzyloxymethyl)-L-lactate (190.1) and 2-bromo-thiazole (190.2), 2-[(S)-2-(benzyloxymethoxy)-propionyl]thiazole (190.3) is obtained with 90% yield, and this is reduced with L-Selectride to a 93:7 mixture (95%) of (1R)-2- O- (benzyloxymethyl)-3-deoxy- 1- (2-thiazolyl)-L-glycerol (190.4) and its (1S)-epimer. Dondoni and Merino 165 have described several analogous chain extensions. In the transformations discussed above, the thiazole heterocycle serves as a masked formyl equivalent (for a related chain extension of nitrones, see Dondoni et al.166'167). In similar reactions furan ensures a C4 unit, and as the furan ring can be diversely substituted, 168 such a methodology is of great synthetic value for chain extensions. The chloroacetic acid-catalyzed reaction ~69 of 2,3-O-isopropylidene-D-glyceraldehyde (191.1) with furan (191.2) gives rise to 37% of an 85:15 mixture of the diastereoisomeric

236

,

SYNTHESIS OF N O N O S A C C H A R I D E S

ASCENDING

T A B L E 1.310 T h e Addition of 2-Trimethylsilylthiazole on Derivatives of Sugars /~Si(CH3)

3

R-CHO *

Educt H-.,c~O

Losi(cH3)~j

~

.R

(Th)

OH

Reaction temperature

Product diastereoselectivity

M.p.

(~

(%)

(~

Yield (%)

114-116

96

Oil

89

105-107

92

Oil

76

~

Oil

75

FOH

Oil

70

Oil

94

0

LO

FG

aldehydo-

CH3

Th

~OH

LoXcH~ O

OXCH3

CH3

anti, > 95

Th

H~c~O

t--~CH~

0

O~'fL_OBn c"H3

CH 3

O~ ~'-

"CH3

L--OBn

~

20

OBn

O

CH3

LoXcH~ CHa

anti, > 95

Th

H ~.c//O

I--~CH3 -OH3

O=~

20

Lo::

~'~HCH3

O~'-

CH3

"OH3

OH3 Th

H-.c~O

0

OH

OBn

L---OBn anti, 67 Th

(R, S) H-.c~.O 0

CH 2

F

OBn CH 3

OBn

CH3 syn : anti = 50 : 50 Th

(R, S) H-.c~O

l

anti, 90

~--O

OXCH3

20

OBn OBn

O

~OHoBn

Tll

H-.c(.O

CH3

OXCH3

~OHogn ---OBn

LoXcH~ I---O

.

OH3

anti, > 95

(continues)

237

1.2. BUILDUP OF SUGARS WITH ASCENDING SYNTHESIS TABLE

(continued)

1.30

Educt

f

H .,.c~O

Reaction temperature

Product diastereoselectivity

(oc)

(%)

(oc)

Yield (%)

Th

Oil

81

Syrup Syrup

84 86

170-172

85

Oil

83

Oil

70

2O

OBn OBn OBn O OH3 OXCH3

CHO

M.p,

OBn

~--OBn

~--OBn CH3 LoXcH~ I--0

0 0

anti, 90

Th

R~oO._~_ CH3 CH3

O'--~CH 3 CH 3 R = CH 3 > 95

R = CH3 R= Bn

R = Bn

CHO

Th

0 O

> 95

OH

O

H3CO C~~ O O ~ C H 3 H3C

CH3

anti, > 95

I

H-.c(.O

20

ogn

)OH

Th

OBn

OBn

---OBn

~---OBn

OBn OBn

Fi---0OBn CH 3 L_oXcm

O CH3 OXCH3

H.,. ~.0 C " ~-----OBn

I-~C%

0:~

CH 3 CH 3

"L__oB:H3

anti, > 95

20

Th OBn t--~CH3 0 ~ "~ -OH3 L--OBn anti, > 86

(continues)


238

(continued)

T A B L E 1.30

Reaction temperature (~

Educt H~c~.O

Product diastereoselectivity (%)

Th

20

t

---OBn

Yield (%)

Oil

55

Oil

80

82-85

71

Oil

68

Oil

68

OBn

----OBn It--~CH3

~---OBn

I--O~CH3 O~"OH3

O =~"'~L.__ OB:- H3 H.~ / O C ~--OBn

Mopo (~

L--OBn anti, 95 Th

20

--OH --OBn

--OBn

OBn

--OBn

--OBn

--OBn

--OBn

--OBn

--OBn

--O~CH 3 O_~ ~'- -CH 3

--O~.~CH 3 01__~'- -OH3

--OBn CHO

20

BnO-~

--OBn anti, > 95 Th HO-BnO--

0 H3C

OH3 CH3 CHO

H3CC ~ ~ C H

20

BnO--~ BnO-- 1

BnO

H3C OH3

O+CH3 CH3 CliO

20

BnO--

BnO--

BnO-O

H3C CH3

anti, 80 Th HO-BnO

3 CH3

R a C e ' o H 3 CH3 anti, 95 Th HO--

BnO-BnO-BnO--

--O

o;

,o

O+CH3 OH3

O --O

H3C CH3

O--~CH 3 CH3 anti, 95


NyS

N& :

oo- 1

oo- 1

R

R

R

189.2

189.3

oO:n

189.1

Selectride

239

NyS

"

oo- 1

F I G U R E 1.189

1-C-(2-furyl)-2,3-O-isopropylidene-D-glycerols (191.3), as shown in Figure 1.191. This procedure has been successfully employed for uloses to produce furylcarbinols with a sugar chain. The diastereoisomeric alcohols can be readily separated by chromatography, and the configurational assignment is carried out by chiroptical methods. As reported by Zamojski et aL, 17~ the O-benzoates of the (R)-series possess a negative CD band at ---230 nm and a positive band at 215-220 nm. The chain extension shown in Figure 1.191 was carried out in furan or in 2-methylfuran, as the solvents, and the r e s u l t s 17~ a r e summarized in Table 1.31. The chain extension with 2-methylfuran was also accomplished through the lithio analog, and in this case the anti-selectivity was found to be higher (95 : 5) than that of the chloroacetic acid-catalyzed transformations (93:7). Chain extension of 2,3-O-isopropylidene-D-glyceraldehyde with the Iithiated derivative of 2-methylfuran: preparation of (2R,3R)-l,2-O-isopropylidene-3-[2-(5methylfuryl)]-l,2,3-propanetriol ~72 To a cooled (-30~ and stirred solution of 2-

methylfuran (15 ml, 166 mmol) in THF (160 ml) is added 1.6 M n-butyllithium in hexane (100 ml), and stirring is continued for additional 4 h by slowly raising the temperature to + 10~ Then anhydrous zinc bromide (36 g, 160 mmol) is added, and the mixture is stirred for 15 min and cooled to -40~ followed by the dropwise addition of a solution of 2,3-O-isopropylidene-i>glyceraldehyde (20.8 g, 160 mmol) in THF (160 ml). It is stirred at this temperature for 4 h, and warmed to 0~ and the reaction is quenched with saturated aqueous ammonium chloride and worked

00202H5

BOM-~

+

/~S~,~

CH a

190.1

BuLi,-78~ Br

90%

~ BOM

Selectride

~

CH3

190.3

190.2

BOM= benzyloxymethyl F I G U R E I. 190

t

~

95%

-~ BOM

OH

CH3

190.4

240

I


H~C~,,O LO CH3 OXCH3 191.1

CO~ ClCH2CO2H

O OH

LO~CH~ O

191.2 FIGURE

CH 3

191.3

1.191

up in the usual manner. HPLC analysis shows a 95 : 5 anti/syn ratio (eluant: 97.5:2.5 heptane-ether). Recrystallization from hexane-ether gives 22.1 g (65%) of the pure title product with m.p. 63-64~ [a]D +29.5 (C = 1.07 in chloroform). 2 , 5 - D i m e t h y l f u r a n can also be r e a c t e d with 2 , 3 - O - i s o p r o p y l i d e n e o - g l y c e r a l d e h y d e at high p r e s s u r e to furnish 22% of ( 1 R S , 2 R ) - I - C (2-furylmethyl)-2,3- O-isopropylidene-glycerol. 173 T h e a d d i t i o n of 2-(trimethylsilyloxy)furane to a l d e h y d e s results in a chain e x t e n s i o n with a Ca unit, c o r r e s p o n d i n g to an a , f l - u n s a t u r a t e d b u t y r o l a c t o n e [ 2 ( 5 H ) - b u t e n o l i d e ] . T h e configuration of the n e w chiral c e n t e r can be influenced by various catalysts, 174 a n d this type of chain e x t e n s i o n has also b e e n i n t r o d u c e d ~75 to the c a r b o h y d r a t e field for the p r o d u c t i o n of oand L-hept-2-enono-l,4-lactones with arabino, ribo, xylo, a n d lyxo configurations f r o m 2 , 3 - O - i s o p r o p y l i d e n e - o - a n d -L-glyceraldehyde, as s h o w n in F i g u r e 1.192. F r o m the r e a c t i o n m i x t u r e the p r e d o m i n a n t two p r o d u c t s ; the arabino- and ribo-lactones can be isolated in 56% a n d 13% yields, respectively. A n o t h e r alduloses, including 3 - O - m e t h y l - l , 2 - O - i s o p r o p y l i d e n e - a - o x y l o - p e n t o d i a l d o - l , 4 - f u r a n o s e , can also be h o m o l o g a t e d , 176 w h e n the final p r o d u c t s are derivatives of fl-L-ribo-D-gluco-nonose. T w o consecutive fourc a r b o n h o m o l o g a t i o n s a77 of 2 , 3 - O - i s o p r o p y l i d e n e - o - g l y c e r a l d e h y d e (193.1) lead to the p e n t a - O - i s o p r o p y l i d e n e derivative (193.9) of o-glycero-o-taloL-ta/o-undecose, a s s h o w n in Figure 1.193. A c c o r d i n g to the results of Casiraghi et al., 178 an o p t i m i z e d chain extension step with 2-(trimethylsilyloxy)-furan is as follows.

6, 7-O- Isop ropylidene-2,3-dideoxy- D- arabino- and D-ribo-hept-2-eno -l, 4- lacA mixture of 2,3-O-isopropylidene-o-glyceraldehyde (10 mmol) and trimethylsilyloxyfuran (2.15 ml, 13 mmol) in dichloromethane (30 ml) is cooled to -80~ and boron trifluoride etherate (1.23 ml, 10 mmol) is added under argon atmosphere. It is then stirred at this temperature for 6 h, saturated aqueous NaHCO3 is added, the temperature is allowed to rise ambient temperature, and the mixture is extracted with dichloromethane. The organic layer is washed with aqueous NaHCO3, dried over MgSO4, and concentrated under reduced pressure. The residue is dissolved in methanol (10 ml), then citric acid (0.25 g) is added and the solution is stirred for 3 h. After dropwise addition of water (5 ml) the mixture is extracted with dichloromethane, the organic layer is dried, and concentrated, and the residue is purified by means of flash column chromatography (eluant: hexane-ethyl acetate) to obtain a 96:4 arabino/ribo mixture (90%). Physical data for the pure arabinot o n e 178

TABLE 1.31

Conversion of aldehydo-Sugars with Furan and 2-Methylfuran Yield Diastereomeric ConfiguratiOn of (%) ratio the major product

Product

Educt

~~

42

85" 15

62

95"5

45

87" 13

68

95" 15

45

86"14

35

75"25

R

OXCH3

H~c~.O

L:

3

CH3 XCH 3

CH3 o OH

Lo•

_?

CHO ~O

~

OH

CH3 H3CCH3

O@CH 3 CH3

=k OCH3

CliO o/~.o H3G

o

~/

~o. oc~ ~

CH3

CliO

O H3c X O OH3 -.-- /

n O@CH 3 OH3

OBn

~

;__~CH3 CH3

CHO

O

B2n BnO

OBn

j~OB2n~ BnO -

" OBn

(continues)

242

I

ASCENDING

TABLE i.31

SYNTHESIS

OF MONOSACCHARIDES

(continued)

Educt

Yield Diastereomeric Configuration of (%) ratio the major product

Product

/~ H3 CliO

~

~OCH 3 OBn OBn

OH

36

73"27

S

76"24

S

~OCH 3 OBn OBn OH3 CHO

OCH3

0

--

~OH

OCH3

OBn OBn OBn OBn

O

CliO

--/

w~OH BnO

OBn

36

0

I OBn BnO

I OBn

OBn

H3C~ O-H3CXO --OH

OSi(CH3)3 (CH3)3SiO3SCF 3 O•-• BF3"Et20 +

H~C.{.O LO OH3 OXCH3

D-xylo

D-nbo

-78~ CH2Cl2 OH3

LoXc~ D-arabino

FIGURE 1.192

HO--'L_O

OH3

/oXc~ D-lyxo

243

1.2. BUILDUP OF SUGARS W I T H ASCENDING SYNTHESIS ~

~

H-.c~O (,) 78 %

LO OH3 OXCH3

F OTMS O OH3 --(OXCH 3

~

193.1

H~cXo--I H~C>..OO--I H3C"

~

H3C_

(iv)

O

_CH3

80 %

F

TMSO--

~O 1---O

L o X c m CH3 193.6

COOMe I

-l~ H3C _O-97 % H3cXo -

~O --O CH3 --O~CH3

H~c~-O

--O .OH3 ---oXcH3 --O CH 3 .......--"~ CH 3

--O _CH3 __oXcH3

(iv)

81% r

H3C O--

H3C.,7"".--...~~--0

--OXCH~ --O

193.7

(ii) -i~ 66 %

H3C-

OH3 L_OXCH 3

(iii)

OO--

O

~ H3CXo--~ 58 % r H3C~---I

193.5

OH OH

~

TMSO H3C_ 0--4

(i)

_..t..._O

193.4

H3C O H3c ~

_

H3c x O H3C~OO__.I t---O

L--oXcH3

H3C_ H3c X

193.3

O--

H3C"

70 %

I---0 OH3 LOXCH3

H" Cd"O

_OJ

(iii)

LOTM s

193.2

COOMe H3C

(i,) 66 %

.CH 3

193.8

--O CH3 O--I ....-~'~ OH3 H3C O-H3CXO H3C. ~ O - H3C- ~ ~ 0

oXcH~ O

CH3

193.9

Reagents: (i) 2-(trimethylsilyloxy)furan(TMSOF), BF3. OEt2, -90~ then Me3SiCI, pyridine; (ii) KMnO4, DCH-18-crown-6, CH2CI2, 15~

(iii) dimethoxypropane,TsOH, room temperature; (iv) DIBAL, CH2Ci2, -90~

FIGURE I. 193

lactone: m.p. 125~ [a]~ +69.6 (c = i in chloroform) and for the pure syrup, [a]~ -79.4 (c = 0.6 in chloroform).

ribo-analog:

The butenolide unit can be built into 3-(tert-butoxycarbonyl)-4-formyloxazolidine as well, and after the necessary transformations a-Dglycero-D-talo-heptopyranose and the corresponding uronic acid, precursors to destomic acid can be prepared. 179 The enantiomeric L-compounds can also be obtained 179 with this highly stereoselective and truly viable route.

244


Most recently 2 - ( t e r t - b u t y l d i m e t h y l s i l y l o x y ) t h i o p h e n e (194.1) has been synthesized and coupled with 2,3-O-isopropylidene-n-glyceraldehyde (194.2) to afford as~ the products 194.3 and 194.4 shown in Figure 1.194. Of the reagents used in saccharide chain extensions, certain p y r role derivatives, especially, pyrrole-derived silyloxydienes, play significant role. In particular, N - ( t e r t - b u t y l c a r b o n y l ) - 2 - ( t e r t - b u t y l d i m e t h y l s i l y l ) p y r role (195.1, T B S O P ) , available 181 from pyrrole, has been found suitable for the chain extension of chiral substrates carrying aldehydo or imino groups, which i s ~ i n many c a s e s ~ a key step in flexible methods aimed at constructing complex molecules bearing multiple contiguous chiral centers. 181-189 As shown in Figure 1.195, t h e sugars 195.2-195.4 are reacted with T B S O P (195.1) in the presence of suitable catalysts (SnC14, tritylperchlorate), and for a practical utilization of this important methodology, two prescriptions are given as follows. 4-Amino-8-O- ben z y l- N- (tert- b utoxycarbon y l) -2,3, 4- trideoxy-6, 7-O- isop rop y lidene-L-galacto-oct-2-enoic acid 1,4-1actam (195.6) 185 A mixture of 4-O-benzyl-2,3-

O-isopropylidene-L-threose (195.3, 2.32 g, 11.27 mmol) and TBSOP (195.1, 3.35 g, 11.27 mmol) in dry ether (50 ml) is cooled to -80~ under argon. Then a i M/dm3 solution of SnC14 in dichloromethane (16.9 ml, 16.9 mmol) is added via a cannula during 10 min, and the solution is stirred for 5 h. The reaction is quenched with saturated aqueous NaHCO3, and the mixture is warmed to ambient temperature and extracted with ether (3 • 15 ml). The organic layer is dried (MgSO4) and concentrated under reduced pressure to furnish the crude lactam, which is purified

t-o•

H~C~,.O

~OTBDMS

194.2

194.1 BF3" Et20, -90~ CH2CI2

O

O

S~ i,

+ H

S

~" H

loXc

Io X

major, 72%

minor, 10%

194.3

194.4

FIGURE 1.194

CH3 OH3

1.2. BUILDUP OF

245

SUGARSWITH ASCENDING SYNTHESIS O

~N "~BOC + OTBDMS

H"c~O I (?HOR)n

catalyst #

f

(?HOR)n CH2OR

CH2OR

195.1

transformations ,,,,>

H~'~BOC

195.5

195.2

O H.,,c~.O N'~ BOc OTBDMS 195.1

+

m~CH

O ~ ~'OBn

3

-CH3

OH

BnO-~ O "~BOC + BnO~ ] "OAc OTBDMS OBn

Ref.

O==~ "OH3 OBn 195.6

195.3

~N

195.1

'~'~BOC

SnCI4 ether, -80~ "~

BnO TrCIO4 ether, O~

~._.___.V'l H BOC OBn

N

Ref. 189)

0

195.4

195.7

FIGURE

I. 195

by flash column chromatography on silicagel (eluant: 65:35 ethyl acetate-hexane) to afford the pure lactam 195.6 (3.42 g, 80%), as a solid with m.p. 96-98~ [a]ZD0 + 134.66 (C = 0.88 in chloroform).

6, 7,9- Tri-O-benzyl-4-N- (tert-butylcarbonylamino)-5,8-anhydro-2,3,4-trideoxyD-glycero-D-galacto-non-2-enono-l,4-1actone (195,7) 189 To a solution of 1-O-ace-

tyl-2,3,5-tri-O-benzyl-o~-D-arabinose (195.4, 1.0 g, 2.16 mmol) in dry ether (10 ml) are added TBSOP (195.1, 770 mg, 2.59 mmol) and anhydrous tritylperchlorate (370 mg, 1.08 mmol) with stirring at 0~ After 4 h, the temperature is allowed to rise to 20~ and, after additional 24 h, the reaction is quenched with saturated aqueous NaHCO3 (15 ml). The mixture is extracted with ether (3 • 20 ml), the organic layer is washed with water, dried (MgSO4), and concentrated. The pure product 195.7 (784 mg, 62%) is obtained by flash column chromatography on silicagel (eluant: 7"3 hexanes-ethyl acetate) as an oil, [a]ZD2 --58.9 (C = 1.6 in chloroform).

1.2.7.3. The Reformatsky Reaction for the Chain Extension of Saccharides This r e a c t i o n , i n v o l v i n g t h e z i n c - m e d i a t e d f o r m a t i o n of fl-hydroxyc a r b o x y l a t e s f r o m h a l o g e n o a c e t a t e s a n d a l d e h y d e s / k e t o n e s 19~ ( R e f o r m a t s k y - r e a c t i o n ) , is e m p l o y e d in c a r b o h y d r a t e c h e m i s t r y for t h e p r e p a r a t i o n of n o n b r a n c h e d onic-acid esters TM (Fig. 1.196).

2.46

I


X~CH~--'-CO2 R1 +

Zn

X--Zn--CHs-.-CO2 R1

R2

R

OH

N / C R2/ \ 0H2002 R1

--,

HC )

R\ R2/

C

/

OZnX

\ 0H2002 R1

FIGURE 1.196

This Reformatsky method was applied for chain extensions with starting materials such as 3-O-benzyl-l,2-O-cyclohexylidene-a-D-xylofuranos-l,4ulose, a92 1,2-O-cyclohexylidene-a-D-xylofuranos-l,4-ulose, a93 2,3:4,5-di-Ocyclohexylidene-aldehydo-L-arabinose, 193 and 2,3:5,6-di-O-isopropylidenea-D-mannofuranose, a93 but the stereochemistry of the newly created chiral center was not determined (cf. Csuk and Gl~inzer194). Then the stereochemistry of a related Reformatsky reaction, carried out with 3- O-benzyl-l ,2O-isopropylidene-a-D-xylo-pentofuranos-l,4-ulose (197.1) and ethyl bromoacetate (197.2), was studied and the anti-configuration was assigned to the product 197o3, suggesting a9~that the reaction proceeds under thermodynamic control (Fig. 1.197). Ethyl 3-O-benzyl-l,2-O-•opropylidene-a-L-ido-heptonate (197,3) 195 A suspension of freshly activated zinc (washed with 20% aqueous HC1, water, acetone, and ether and then dried; 655 mg, 10 mmol) in benzene (10 ml) is heated to reflux, and a mixture of the sugar 197.1 (2.0 g, 7.2 mmol), ethyl bromoacetate (1.6 ml, 14.4 mmol), and ether (3 ml) is added and the reaction mixture is kept under reflux for an additional 30 min. It is then hydrolyzed with 20% aqueous sulfuric acid and extracted with dichloromethane. The crude product obtained on usual workup is purified by means of column chromatography to yield 2.24 g (85%) of the pure syrupy heptonate 197.3 with [a]D --22 (C = 2 in chloroform).

For the preparation of 2-deoxy-2,2-difluoro-D-ribose, the Reformatsky chain extension was selected, ~96 and thus 2,3-O-isopropylidene-DO202H CHO

CH 2 n

+

BrCH2CO2C2H5

O--~--CH 3 CH3

1 Zn '

,.._

2, H (~

~

~

O

.

OBn O~CH CH 3

197.1

197.2

FIGURE 1.197

197.3

3

1.2. BUILDUP OF

SUGARS WITH ASCENDING SYNTHESIS

247

glyceraldehyde (198.1) was treated (Fig. 1.198) with the commercially available ethyl bromodifluoroacetate (198.2) to obtain a ---3:1 mixture of ethyl 2,2- difluoro- (3R) - hydroxy- 3 - (2,2-dimethyl- 1,3 - dioxolan- 4- yl)propionate (198.3) and the corresponding (3S)-hydroxy isomer (198.4). Then the (3R)hydroxy derivative 198.3 was transformed in three further steps ~96 into 2-deoxy-2,2-difluoro-o-ribose, and the L-enantiomer was also synthesized 197 according to this procedure. Ethyl 2,2-difluoro- (3R)-hydroxy-3- (2,2-dimethyl-l,3-dioxolan-4- yl)propionate (198.3) and the corresponding (3S)-hydroxy isomer (!98.4) 196 To 24.9 g of activated zinc is added a small portion of a solution consisting of 55 g of 2,3-0isopropylidene-D-glyceraldehyde (198.1) and 77.3 g of ethyl bromodifluoroacetate (198.2) in dry THF (129 ml) and dry ether (129 ml). The reaction mixture begins to reflux as soon as the first addition to the activated zinc is made. The remainder of the solution is added dropwise at a rate to maintain gentle reflux throughout the addition time of ---30 min. The mixture is stirred under a gentle reflux for an additonal 30 min, and then poured into 480 ml of 1 N hydrochloric acid and 480 g of ice, and the mixture is stirred until all the ice has melted. The aqueous mixture is extracted with ether (4 • 170 ml), the combined organic layer is washed with saturated aqueous NaC1 and saturated aqueous NaHCO3, dried over MgSO4, and evaporated to obtain 104 g of a light-yellow syrup. This crude product is chromatographed on a 4-kg silicagel column (eluant: chloroform containing 0.5% of methanol) to isolate first 20 g of the minor (3S)-hydroxy isomer 198.4, followed by the elution of 62 g (65%) of the (3R)-hydroxy sugar 198.3 in an essentially pure form.

When the reaction was performed in acetonitrile, 45% of a 1.8:1 mixture of the 3R- and 3S-isomers (198.3 and 198.4, respectively) was obtained by Japanese researchers. 198 Reformatsky conditions were also applied in a novel synthesis 199 of N-acetylneuraminic acid. The key step of this procedure, shown in Figure 1.199, is the chain extension 199 of 2-acetamido-2-deoxy-3,4:5,6-di-O-isopropylidene-aldehydo-n-mannose (199.1) with tert-butyl 2-(bromomethyl)prop-2-enoate (199.2). Of the various agents applied for the coupling of the two reaction partners, the highly reactive Zn/Ag couple on graphite was found to be more efficient than activated zinc, leading to the formation of a ---9:1 mixture of the two isomeric esters, 199.3 and 199.4.

CO2C2H5

H..c~O LO

CH3 + BrCF2CO2C2H5

198.1

OH

F

+, H O

LoXcH3 hoXcH~ O

198.2 FIGURE

CO2C2H 5 F

1, Zn 2, H(~)

oXcH3

.

1.198

. CH 3

O

(3R)

(3S)

198.3

198.4

OH3

I

~48


H

znA0 AoHN Ac::

AcHN~1

O==:JI'~.=/CH3 + Br!----O'~"" CH3 |~---O OH3

O2Bu t

~

CO2Bu-t

on graphite

~--

'----0~CH3

199.1

O =~..~.~/CH3 ~-~o~CH3 I---O_

_CH3

LoXcm

199.2

199.3

+

cO2gu t

O ~ jCH3 ~-- O"~"" OH3 I---O_

_CH3

LoXcm

199.4

FIGURE 1.199

tert-Butyl 5-acetamido-2,3,5-trideoxy-6,7:8,9-di-O-isopropylidene-2-methylideneD-glycero-D-galacto-nononate (199.3) and the corresponding D-glycero-D-taloisomer (199.4) 199 Graphite (2.5 g, 208.14 mmol) is heated under argon at 150~ for 20 min, and under vigorous stirring, freshly cut clean potassium (0.98 g, 25.06 mmol) is added in several pieces over 5-10 min. Heating and stirring are continued for 30 min, and the bronze-colored CsK is allowed to cool to room temperature and suspended in dry THF (100 ml). A mixture of anhydrous zinc chloride (1.7 g, 12.47 mmol), and silver acetate (0.21 g, 1.26 mmol) is added in three portions. After heating under reflux for 30 min, the mixture is cooled to -78~ and a solution of the ester 199.2 (2.8 g, 12.66 mmol) and the sugar 199.1 (3.0 g, 9.96 mmol) in dry THF (20 ml) is slowly added through a syringe. After stirring for 30 min at -78~ the temperature is allowed to warm to 0~ over 1 h, the mixture is filtered through Celite, and the filtrate is evaporated to give an oil (199.3/199.4 = 88-91:8.8-11.1, HPLC, Zorbax Sil, 3:1 ethyl acetate-hexane, 1.5 ml/min). Column chromatography of this mixture on silicagel (eluant: 2:1 ethyl acetate-hexane) gives 3.7 g (83.7%) of 199.3, m.p. 84-86~ [o~]~ +9.65 (c = 0.2 in chloroform) and 0.42 g (9.5%) of 199.4, [a]~ + 10.7 (c = 1.9 in chloroform). F o r the p r e p a r a t i o n of 2,6-anhydro-tiept-3-uloses (with D-gluco a n d D-manno configuration) and 3,7-anhydro-oct-4-uloses f r o m ulosyl bromide, zoo R e f o r m a t s k y conditions w e r e also applied w h e n the r e a c t i o n partn e r was f o r m a l d e h y d e or a c e t a l d e h y d e . Starting f r o m aldosuloses, C-linked disaccharides can be o b t a i n e d , 2~ a n d in such reactions C e C 1 3 - - N a I was f o u n d to be a m o r e efficient coupling a g e n t t h a n the Z n - - C u c o u p l e (see Fig. 1.200). J a p a n e s e a u t h o r s r e p o r t e d successful R e f o r m a t s k y r e a c t i o n with acylated sugars for the synthesis 2~ of ethyl 3,6-anhydro-4,5,7-tri-Obenzoyl-o-ribo-heptonate. T h e chain e x t e n s i o n r e a c t i o n of 2 , 3 - 0 i s o p r o p y l i d e n e - D - g l y c e r a l d e h y d e with ethyl b r o m o a c e t a t e can be ind u c e d 2~ with tin, indicating that o t h e r m e t a l s are also sufficient to p e r f o r m the R e f o r m a t s k y reaction. O f these metals, i n d i u m is to be m e n t i o n e d h e r e , b e c a u s e it has b e e n successfully e m p l o y e d for the chain e x t e n s i o n of u n p r o t e c t e d saccharides via their formyl groups. 2~176 Thus, i n d i u m m e d i a t e d coupling 2~ of l o w e r m o n o s a c c h a r i d e s with a - ( b r o m o m e t h y l ) acrylic acid gives the c o r r e s p o n d i n g adducts in g o o d yields, w h o s e f u r t h e r t r a n s f o r m a t i o n s allow the p r e p a r a t i o n of biologically i m p o r t a n t m o n o s a c -


CHO

;-% +

BzO~ ~

249

\~Br

O o

H3C

O

O+CH 3 OH3

Zn-Cu i or CeCI3-Nal

H3C 0 ~I OH3

.~-o.z~ BzO

H3C _OH3

f-~

c ~~: \ oO OHO

~o~z X - ~ ~ c ~ O ~ oH~OH ~

+

BzO ",4

~H

3

8"1 FIGURE

1.200

charides, such as Kdo or Neu5-Ac. Precursors to these natural products can be obtained from N-acetyl-D-mannosamine (201.1) (Fig. 1.201). 5-Acetamido-2,3,5-trideoxy-2-methylidene-o-glycero-o-galacto-nononic acid (201.2, X = N H A c ) 2~ To a stirred mixture of N-acetyl-D-mannosamine (201.1,

957 mg, 4.0 mmol) and c~-(bromomethyl)acrylic acid (3.96 g, 24 mmol) in ethanol (24 ml) and 0.1 N HC1 (4 ml) is added indium powder (1.84 g, 16 mmol). The

H..c~O X

HO

OH

OH

+

CO2H

Irl

'~CO2H ~OH X m

HO~

Br

OH 201.1

X = NHAc

X = OH

~OH ~OH ~OH

IOH

201.2

201.3

~

X= NHAc --~ FIGURE

1.201

ACO2H HO~ X~ HO ~OH ~OH

Kdo

NANA

250

I


reaction mixture is heated at 40~ with a sealed cap. After 12 h, the small indium clump is removed from the solution, extra indium powder (920 mg, 8 mmol) is added, and the mixture is heated for another 12 h. After being cooled to ambient temperature the mixture is filtered through a pad of Celite, it is rinsed with water, and the combined aqueous solution is deionized with Dowex 50 • 2-100 (H +) (5 g, dried weight), filtered, and evaporated to dryness below 30~ Water (10 ml) is added, and the precipitate is filtered. The filtrate is lyophilized to give a colorless syrup that is chromatographed on Dowex 1 x 8-100 (formate form) anion-exchange resin by eluting with a 0-2 N formic acid gradient. The fractions (TLC: 7:3 2-propanol-water) with R f - 0.44 (tailing) contain the desired product 201.2. These are combined and lyophilized to afford 943 mg (77%) of the pure title product. W h e n l a c t o n e s a r e t r e a t e d w i t h t h e d e r i v a t i v e s of b r o m o a c e t i c a c i d u n d e r R e f o r m a t s k y c o n d i t i o n s , t h e e s t e r s of u l o s o n i c acids a r e p r o d u c e d . T h e r e a c t i o n of 2 , 3 : 5 , 6 - d i - O - c y c l o h e x y l i d e n e - D - m a n n o n o l a c t o n e w i t h e t h y l bromoacetate led to ethyl 4,5:7,8-di-O-cyclohexylidene-2-deoxy-D-manno3 - o c t u l o s o n a t e , a n d s i m p l e d e r i v a t i v e s of this c o m p o u n d (e.g., a m i d e , m e t h y l g l y c o s i d e ) a r e a l s o a v a i l a b l e . 195,2~ A v e r y s i m i l a r c h a i n e x t e n s i o n o f 2 , 3 : 5 , 6 - d i - O - i s o p r o p y l i d e n e - D - g u l o n o l a c t o n e (202.1), g i v i n g rise 21~ t o a s i n g l e i s o m e r 202.2 e x c l u s i v e l y , is s h o w n in F i g u r e 1.202. E t h y l 2- d e o x y - 4,5:7,8- di- 0 - i s o p r o p y l i d e n e - a - D- g u l o - 3 - o c t u l o f u r a n o s o n a t e (202.2) 21~ A three-necked flask is heated in an oven and cooled in a nitrogen

atmosphere. Then it is equipped with a KPG stirrer, a reflux condenser, and a dropping funnel. In the flask is placed activated zinc powder (2.7 g), and in the dropping funnel is placed a solution of 2,3:5,6-di-O-isopropylidene-D-gulono-l,4lactone (202.1; 4 g, 15.5 mmol) and ethyl bromoacetate (7.2 g, 43 mmol) in 1,4dioxane. A few milliliters of this solution is added to the zinc, and by the addition of a few crystals of iodine, the reaction is initiated. The mixture is stirred and warmed to 40-50~ and the remainder of the preceding solution is added dropwise at this temperature when the color changes into green. Then the mixture is cooled to room temperature, and water (40 ml) is added and evaporated to dryness. The solid residue is rinsed with a solution of acetic acid in ether (5 • 30 ml of 10% acetic acid in ether), and the ethereal phase is separated, dried, and concentrated to a syrup that consists of (TLC, 9:1 chlorofom-methanol) a major product with R f - 0.71 and three more slowly migrating by-products. The major product, 202.2 (2.69 g, 50%), is obtained by column chromatography (eluant: 9:1 chloroformmethanol) as a syrup that crystallizes from chloroform-hexanes in 4 weeks by storing in a deep-freezer, m.p. 39.5-40~ [a]~ -12.7 (c = 1.04 in chloroform). O

O

S.' o O

O

+

BFCH2CO2C2H5

_

~

O

CH 3

O

OH 3

L-oXc. !---.0

CH2CO2C2H5

LoXc =

CH 3

i---O

202.1

OH 3

202.2 FIGURE

1.202

251

1.2. BUILDUP OF SUGARS W I T H ASCENDING SYNTHESIS

T h e R e f o r m a t s k y r e a c t i o n of l a c t o n e s can be p e r f o r m e d u n d e r t h e r e a c t i o n c o n d i t i o n s ~95 s h o w n in F i g u r e 1.199. A n efficient g e n e r a l p r o c e d u r e for t h e c o n d e n s a t i o n of f u r a n o i d a n d p y r a n o i d a l d o n o l a c t o n e s w i t h o r g a n o z i n c r e a g e n t s d e r i v e d f r o m d i f f e r e n t h a l o a l k a n o a t e s a n d t h e zinc/ s i l v e r - g r a p h i t e surface c o m p o u n d , a n d l e a d i n g to c h a i n - e x t e n d e d 3- or 4 - u l o f u r a n o s - (or - p y r a n o s ) o n a t e s in high yields, is as follows. General procedure for Reformatsky-type reactions TM Graphite (Fluka, 0.78 g, 65 mmol) and clean potassium (0.33 g, 8.44 mmol) are stirred at 150~ under argon as described on page 248 by Csuk et al. 199To the resulting bronze-colored C8K suspended in dry THF (20 ml), a mixture of anhydrous zinc chloride (0.55 g, 4.1 mmol) and silver acetate (0.06 g, 0.36 mmol) is added in several portions at room temperature with vigorous stirring. The addition of these salts causes the solution to boil. Refluxing is continued for an additional 20 min, the suspension is cooled to -40~ and a solution of 3.3 mmol of the lactone and 4.3 mmol of the haloester in dry THF (5 ml) is slowly added. After stirring at this temperature for 20 min, the mixture is allowed to warm to 0~ stirred further for 30 min, filtered through a pad of Celite, diluted with ethyl acetate (50 ml), and washed with icewater (5 ml) and brine (5 ml). The organic layer is dried (NazSO4), the solvents are evaporated below 35~ and the residue is subjected to column chromatography (eluant: 1:5 ethyl acetate-hexane) to afford the pure products.

T h e so-called Blaise r e a c t i o n , 19~ i n c l u d i n g an a n a l o g o u s t r a n s f o r m a tion of nitriles (203.1) with alkyl b r o m o a c e t a t e s (203.2) in t h e p r e s e n c e of zinc, gives rise to an ester (203.3) as t h e final p r o d u c t , e x t e n d e d with two c a r b o n a t o m s in t h e chain (Fig. 1.203). B u c h a n a n et aL 212 h a v e a p p l i e d this m e t h o d o l o g y for t h e chain e x t e n s i o n of 2 , 3 - O - i s o p r o p y l i d e n e - 4 - O ( m e t h a n e s u l f o n y l ) - D - e r y t h r o n o n i t r i l e (203.4) to t h e u n s a t u r a t e d C6-ester

203.5. Methyl (E/Z)-3-amino-2,3-dideoxy-4,5-O-isopropylidene-6-O- (methanesulfonyl) ~erythro-hex-2-enonoate ( 2 0 3 , 5 ) 212 TO a hot suspension of activated zinc (6.24 g, 5 eq.) in THF (58 m) 0.1 ml portions of ethyl bromoacetate are added until a vigorous reaction starts. When the color of the mixture remains steadily green, a

R--C--N

+

R~- C H --CO2R 2 I Br

203.1

Zn

~ ~

R1 I --CO2R 2 CH I zC R "< NZnBr

OH Q 9

,..= ,v

R/C'~O

203.2

203.3 H

CN mO

R1 I --CO2R 2 CH I

_OH3

mOXCH3 CH2OSO2CH 3

BrCH2CO2CH 3 Zn, THF

H2N." z C . . C >" CO2CH 3 --O

OH 3

--OXCH3 CH2OSO2CH 3

203.4

203.5

FIGURE 1.203

252

I

ASCENDING SYNTHESIS OF. MONOSACCHARIDES

solution of the nitrile 203.4 (4.5 g) in THF (19 ml) is added dropwise over 5 min, followed by the dropwise addition of ethyl bromoacetate (7.36 ml, 4 eq) over 45 min. The mixture is warmed further for 10 min, cooled to ambient temperature, a n d diluted with THF (167.6 ml), and the reaction is quenched with 50% aqueous K2CO3 (27.8 ml). After vigorous stirring for 45 min, the mixture separates into two phases. The upper, organic layer is separated, the aqueous layer is extracted with THF (4 x 50 ml), and the combined organic layer is dried and concentrated, and the residue is chromatographed first on Florisil and then on Kieselgel (eluant: ether), to obtain first 0.135 g (2.2%) of the syrupy (E )-isomer, and then-eluted second-4.61 g (78%) of the pure major product (Z)-203.5, m.p. 97-98~ [a]~ -156.6 (c = 1.66 in chloroform). 1.2.7.4. P r e p a r a t i o n o f S u g a r D e r i v a t i v e s by M e a n s o f C h a i n E x t e n s i o n Based on Aldol-Condensation This c h a i n e x t e n s i o n s t r a t e g y utilizes t h e b a s e - c a t a l y z e d t r a n s f o r m a t i o n (Fig. 1.204) of a l d e h y d e s a n d k e t o n e s (204.1), c o n t a i n i n g an active m e t h y l e n e g r o u p at t h e a - p o s i t i o n , a n d f u r t h e r c o n v e r s i o n of t h e

\ /

CH--C--R II O

~"

OH (E)

""

arabinose238

To a solution of sodium carbonate (8.2 g, 77.36 mmol) and D-arabinose (15.53 g, 103.5 mmol) in

260

clio

ASCENDING SYNTHESIS OF HONOSACCHARIDES

,

1

Li / O

OH2

OBn~ O

+ LiN[Si(CH3)3]2

O--~CH3

THF -50~ ~-30~

/

CH~

O--~CH~ I

L

OH~j

213.1

213.2

/,,nO',

CHO

o

200 ,

213 3

o

H" C~I(5R)

0

(6R)~OH

Ii

I1

H '" ct.. (5S)

(6S), ,,OH n

&~cH3Bn6"NI9 ~~ ()C== OBn CH3

'o-X- CH3,,nO"

OBn

C.~

CH 3

213.4

213.5

6-1 FIGURE

i.213

water (40 ml), oxaloacetic acid (5 g, 37.86 mmol) is added slowly, the pH is adjusted to 11 with 10 N NaOH, and the mixture is stirred for 90 min. It is then acidified (pH = 1-2) with Amberlite IR-120 (H +) ion exchange resin, filtered, and neutralized with ammonium hydroxide. The product is chromatographed on an Amberlite CG400 column (HCO~ form, 60 • 3.5 cm), washed with 3 liters of water, and eluted with 0.5 M ammonium hydrogencarbonate solution (4 liters). The eluate is concentrated to 50 ml under reduced pressure and freeze-dried. Following crystallization, the residue gives 3.60 g (37%) of Kdo, m.p. 118-122~ [a]~ +32 (c = 2.0 in water).

In a novel study 239 the final step of the ulosonic acid synthesis was investigated, and it was established that the decarboxylation can be facilitated with 1 mol% of NiC12 (with respect to oxaloacetic acid) and thereby the yield can be increased up to 66%. The reaction of D-mannose with oxaloacetic acid (Fig. 1.215) has also been studied, 239and after optimization, the overeall yield of the produced ammonium salt of 3-deoxy-D,glycero-~D-galacto-non-2-ulosonic acid (215.1), together with the corresponding Dtalo-epimer 215.2, is --~70%, and it is important to keep the pH between 5


261

CO2H I

C=O I 2 OH HO HO

H HO ,,~~ J' CH2OH

CH20 H

"

H(3

H ~O

O~

H

OH OH

HO~~@

cO2H

O

H

/OH

OH

CO2H

OH 214.1

Q

O.

-C I II "O~c~C~

H

O. i'C

H

~

H

"~

/C : O

co2- /*

I-I--

R

C--O

CO 2-

J

1

HC~,,OH

C--O

O

I

1

R

CH 2 I

-CO 2

HC'~,OH I

R R= sugar portion

FIGURE 1.214

~

HO. VOHo

o~OH HO1~

H

OH

CO2HI 1, Na2CO3+ NaOH 215.1 C-O 2, NiCI2, pH = 5-6 OH +/H2 50 - 60~ ~+ CO2H HO /r------O OH ~OH

~CO2H~

HO"

~

OH ]

OH HO

OH / J

C

OH O 2

215.2

R : HO~[~O H OH 215.1

FIGURE i.215

215.2 9 = 42 ' 12

CO2H

OH H

262


a n d 6. If n o n i c k e l c h l o r i d e is a d d e d t o t h e r e a c t i o n m i x t u r e , t h e / ~ - D - g a l a c t o i s o m e r (215.1) c a n b e o b t a i n e d 24~ w i t h 39% y i e l d , as f o l l o w s .

Preparation of the ammonium salt of 3-deoxy-D-glycero-B-D-galacto-non-2ulosonic acid (215,1) 240 To a solution of I>mannose (27.03 g, 150.03 mmol) and NazCO3 (6.36 g, 60 mmol) in water (32 ml) oxaloacetic acid (6.61 g, 50 ml) is added slowly, the pH is adjusted to 10, and the mixture is stirred for 2 h and then acidified with Dowex 50 (H +) to pH = 1-2. After filtration, the filtrate is neutralized with ammonia, and the product is purified on a Dowex i column (in HCO5 form), which is washed first with water (2 liters) and then eluted with a 0.3 M solution of formic acid. The eluate is evaporated under diminished pressure, treated with ammonia, and freeze-dried to obtain 5.6 g (39%) of the amorphous product 215.1, [o~]~ -41 (in water). A n a d d i t i o n a l a l d o l r e a c t i o n , d e s c r i b e d b y Szab6241 a n d i n v o l v i n g t h e c o n d e n s a t i o n of 2 - O - b e n z y l - 4 - O - f o r m y l - D - a r a b i n o s e ( 2 1 6 . 1 ) w i t h o x a l o a c e tic acid, a l l o w s t h e i s o l a t i o n of t h e t w o i s o m e r i c o c t - 2 - u l o s o n a t e s , 216.2 a n d 216.3, as s h o w n in F i g u r e 1.216.

Methyl 5-O-benzyl-3-deoxy-D-manno- (216.2) and-D-gluco-oct-2-ulosonate (216.3)241 The pH of a cooled solution of oxaloacetic acid (13.2 g, 0.1 mol) in 2 M aqueous sodium tetraborate (100 ml) is rapidly adjusted to 1.5 with 5 M aqueous NaOH, and 2-O-benzyl-4-O-formyl-D-arabinose (216.1, 5.36 g, 0.02 mol), followed by a solution of nickel chloride (1.2 g) in water (2 ml) is added. The reaction mixture is kept at room temperature for 18 h (the pH of the solution is periodically adjusted to 11.5 with 5 M aqueous NaOH during the first 5 h), at which time the yield of the 3-deoxyulosonates is usually more than 50% (estimated by the thiobarbiturate reaction on 5/,i,1 of the reaction mixture). The reaction mixture is diluted (250 ml) with water and its pH brought to 4 with Amberlite IR-120 (H +) resin. The filtered solution is diluted (500 ml) with a 1:4 mixture of 1 M aqueous pyridinium acetate (pH 5)-ethanol, which causes rapid decarboxylation of the excess of oxaloacetic acid. The solution is stirred under vacuum until evolution of gas ceases (,--30 min), then passed through a column (3.2 x 28 cm) of Lewatit MP 5080 resin (OH-) (60-80 mesh, Merck) equilibrated with 0.25 M aqueous pyridinium acetate (pH 5)-ethanol (1:1 v/v). Elution is effected using a gradient resulting from a constant volume (1 liter) mixing chamber containing 0.25 M aqueous pyridinium acetate (pH 5)-ethanol (1 : 1 v/v) and a reserve chamber (1.2 liters) containing 0.5 M aqueous pyridinium acetate (pH 5)-ethanol (1:1 v/v). Fractions containing 3-deoxyulosonic acids (thiobarbiturate test) are combined and concentrated to dryness. After drying (over KOH pellets), the residue is dissolved in water and passed through a column (1.4 • 17 cm) of Amberlite IR-120 (H +) resin. The neutralized eluant (1 M aqueous

OHC

Bn OH 216.1

1, NiCI2, Na2B404 ~ ~ r - - OHo CO2H NaOH r OH HO OH+ C=O 20~ 2 ".-- BnO /~----O + BnO I ,,-OH CH2 2' CH3OH'D~ ' ~--~OH , ~ CO2H 0020H3 OH 216.2

(D-manno) FIGURE 1.216

216.3

(D.-gluco)

OH CO~CH3 z


26~

ammonium hydroxide) is concentrated to give a syrup that is dissolved in ethanol (20 ml), and any insoluble material is removed by centrifugation. The crude ammonium salts (4 g) are precipitated by addition of ether [paper electrophoresis in 0.1 M pyridinium acetate buffer pH 3.5 showed, besides 216.2 and 216.3 (Rpicric acid 0.7), two major impurities (silver nitrate-sodium hydroxide) having Rpicric acid = 1.13 and 1.5], and are recovered by centrifugation, suspended in methanol, and stirred overnight at room temperature with dry IR-120 resin (H +, 25 ml). The filtered solution is concentrated to give a yellow syrup (3.5 g) that contains two major compounds (TLC in 1"1 chloroform-methanol) with the major, Rf = 0.23 giving, after degradation, 242 3-deoxy-glucitol, a product derived from 3deoxy-I>manno-oct-2-ulosonic acid (216.2), the other (Rf = 0.27) giving 3-deoxygalactitol, the degradation product of the D-gluco-isomer 216.3. The two isomers are separated on a Lobar C (Merck) column (eluant: 9"1 chloroform-methanol), to obtain 1.1 g of the pure D-manno compound 216.2, m.p. 126-127~ (after two recrystallizations from chloroform), [c~]~ +47.4 (c = 1.15 in methanol). =

Various representatives of sialic acid analogs can also be synthesized chemically by the aldol condensation methodology instead of the formerly applied enzymatic methods. 243 The synthesis of sialic acid derivatives (also known as N-acetylneuraminic acid analogs), playing important roles in many biological and immunologic processes, is still a great challenge for synthetic carbohydrate chemists. The first successful synthesis of N-acetylneuraminic acid (217.6, 5-acetamido-3,5-dideoxy-o-glycero-D-galacto-2nonulopyranosonic-l-acid) was carried out by the aldol condensation of 2acetamido-2-deoxy-D-glucose with pyruvic acid 244 or oxaloacetic acid. 245 Kuhn and Baschang 246 have elaborated imporved procedures (Fig. 1.217) starting with 2-acetamido-2-deoxy-D-mannose (217.1) or 2-acetamido-4,6-O-benzylidene-2-deoxy-D-glucose (217.2) and di-tert-butyloxaloacetate (217.3). The application of the easily available glucose derivative 217.2 can be attributed to a facile epimerization 247 under the alkaline conditions employed. Earlier studies showed that the reaction of aliphatic aldehydes with diethyl oxaloacetate leads 248 to carbethoxylactones, which are transformed into a-keto-y-lactones on the action of dilute mineral acids. This observation was applied for N-acetyl-D-mannosamine (217.1), and di-tert-butyl oxaloacetate (217.3) was found to be a very useful reaction partner 25~ to produce the carboxylactone 217.4 by loss of isobutylene. Then decarboxylation of this latter compound in hot water (90-100~ gave rise to the desired y-lactone (217.5) of N-acetylneuraminic acid together with a few byproducts. In practice the condensation of 2-acetamido-4,6-O-benzylidene2-deoxy-D-glucose (217.2) with the ester 217.3 in 1,4-dioxane-methanol is recommended, when no previous gluco ~ manno epimerization is necessitated, and the overall yield is --~30%. A detailed procedure for the execution of the synthesis is as follows. Synthesis of N-acetylneuraminic acid (217,6) 250 Preparation of the potassium salt of di-tert-butyl oxaloacetate The potassium salt obtained 249 by the condensation of i mol of di-tert-butyloxalate 251 and 1 mol of tert-butylacetate is quickly

264

I

ASCENDING

SYNTHESIS OF M O N O S A C C H A R I D E S

0

0

HO

HO2C V OH K(~ C)cHCO2t-C4H9 O I CH3OH .--~ AcHNq )H AcNH[~OH + oerythro-L-ido-L-gulo-dodecitol (272.4): c o l o r l e s s oil, [ a ] ~ + 5 3 (c = 0.69 in d i c h l o r o m e t h a n e ) .

The scope and effectiveness of the radical chain extensions are supported by novel results dealing with the synthesis of the C-glycosyl analogs of O-glycosyl-serine. In these experiments the reaction partner of the glycosyl halides are C-methylenemalonester, 436 or more preferably, a suitable dehydroalanine derivative. 437From the three glycosyl halides (acetobromoD-galactose, acetobromo-D-glucose, and acetobromo-D-lactose; 273.1, 273.2, and 273.3, respectively) shown in Figure 1.273 only the a-anomeric Cglycosyl amino acids (273.10-273.20) are produced in the tributyltinmediated reaction with the dehydroalanine derivatives 273.4-273.9, with a predominance of the (S )-configuration of the newly developed asymmetric center.

R2

R1 .OAc 2 R A ~ Br

OH2 R4 + R3HN" C~C~ II O

\\ 5

0

AcO3~4"O R3HN~

\ \ o~o

OAc

+

R4

AcO..~ O R3HN% 1

O 273.1-3

273.4-9

(S)-273.10--20

R4O

(R)-273.10q20

Synthesis of C-glycosides 273.10-20 via radical addition ofglycosylbromides on dehydroalanine derivatives. (S) and (R) refers to the configuration at C-2. 273.1: R t= OAc, R 2 = H; 273.2: R i = H, R 2 = OAc; 273.3: R 1 = H, R 2 = O-(2,3,4,6-Tetra-O-acetyl-13-D-galactopyranosyl); 273.4: R 3 = Fmoc, R 4 = OBzl; 273.5: R 3 = Z, R 4 = OBzl; 273.6: R 3 = Boc, R 4 = OBzl; 273.7: R 3 = Fmoc, R 4 --- Ph-OBzl; 273.8: R 3 = Fmoc, R 4 = D-Ph-OBzl; 273.9: R 3 = Fmoc-Pro, R 4 = AlaOBzl; a): Bu3SnH, AIBn, dry toluene, 50-65 ~

Bromide

Dehydroalaninederivative

Producff

Yield (%)

S 9R

273.1

Fmoc-AAla-OBzl

273.4 Fmoc-Ala(TA-gal)-OBzl

(S)-10/(R)-10

65 %

2,5 : 1

273.1

Z-AAla-OBzl

273.5 Z-AIa(TA-gal)-OBzl

(S)-ll/(R)-ll

60 %

2.4 : 1

273.1

Boc-AAla-OBzl

273.6 Boc-Ala(TA-gal)-OBzl

(S)-12/(R)-12

61%

3.8 : 1

273.2

Fmoc-AAla-OBzl

273.4 Fmoc-Ala(TA-glc)-OBzl

(S)-13/(R)-13

73 %

2,6 : 1

273.2

Z-AAla-OBzl

273.5 Z-Ala(TA-glc)-OBzl

(S)-14/(R)-14

55 %

2.3 : 1

273.2

Boc-AAla-OBzl

273.6 Boc-Ala(TA-glc)-OBzl

(S)-15/(R)-15

65 %

3.8 : 1

273.3

Fmoc-AAla-OBzl

273.4 Fmoc-Ala(HA-lac)-OBzl

(S)-16/(R)-16

55 %

1.9 : 1

273.3

Z-AAla-OBzl

273.5 Z-Ala(HA-lac)-OBzl

(S)-17/(R)-17

13 %

3.2 : 1

273.1

Fmoc-AAla-Ph-OBzl

273.7 Fmoc-Ala(TA-gal)-Ph-OBzl

(S)-18/(R)-18

45 %

1.6 : 1

273.1

Fmoc-AAla-D-Ph-OBzl

273.8 Fmoc-Ala(TA-gal)-D-Phe-OBzl (S)-19/(R)-19

23 %

>_2.0 1

273.1

Z-Pro-AAla-OBzl

273.9 Z-Plo-Ala(TA-gal)-Ala-OBzl

40 %

1.0 : 1

"(5) and (R) refers to the configuration of C-2 in the glycosylated amino acids.

FIGURE 1.273

(5)-20/(R)-20

343


A n o v e l a p p l i c a t i o n of t h e highly n u c l e o p h i l i c glycosyl radicals is associa t e d w i t h t h e c h e m i c a l synthesis of biologically i m p o r t a n t t a r g e t m o l e c u l e s . S y n t h e s e s of K d o w i t h radical r e a c t i o n s h a v e b e e n p e r f o r m e d by G i e s e 436,438 a n d B r a n c h a u d 439 a n d t h e i r colleagues. T h e a s c e n d i n g step of o n e of t h e m e t h o d s l e a d i n g to K d o (Fig. 1.274) involves t h e c a r b o n - c a r b o n c o u p l i n g of ( 5 S ) - l , 2 , 3 , 4 - t e t r a - O - a c e t y l - 5 - b r o m o - c ~ - n - l y x o p y r a n o s e (274.1) with tertbutyl ( 2 - t r i b u t y l s t a n n y l m e t h y l ) p r o p e n o a t e (274.2). D e t a i l s for t h e p r e p a r a tion of t h e starting b r o m o s u g a r , as well as of t h e k e y step in t h e p r o c e d u r e ( b o t h radical r e a c t i o n s ) , are given a c c o r d i n g to t h e w o r k of G i e s e a n d L i n k e r . 438

(5S)-l,2,3,4-Tetra-O-acetyl-5-bromo-c~-o-lyxopyranose (274.1) 438 A mixture of 1,2,3,4-tetra-O-acetyl-c~-o-lyxopyranose (2.39 g, 7.5 mmol) and freshly recrystallized NBS (6.68 g, 37.5 mmol) in dry carbon tetrachloride is irradiated with an OSRAM Power Star HQI-T lamp (400 W) and allowed to heat under reflux. After 1 h the dark-red mixture is cooled to ambient temperature and filtered, and the solid is washed with carbon tetrachloride (2 • 30 ml). The filtrate is concentrated in vacuo and immediately purified by flash column chromatography (silicagel, 3:1 pentaneethyl acetate) to afford pure 274.1 (1.05 g, 35%) as a white solid, m.p. 123-125~ tert-Butyl 1,2,3,4-tetra-O-acetyl-6, 7-dideoxy-7-methylene-c~-o-manno-octopyranuronate (274.3) 438 In an argon-flushed flask a solution of the bromide 274.1 (500 mg, 1.26 mmol) and the stannane 274.2 (1.63 g, 3.78 mmol) in dry benzene (15 ml) is heated under reflux. At this temperature a solution of AIBN (40 mg, 0.24 mmol) in dry benzene (2 ml) is added dropwise over 1.5 h, and stirring is continued at 80~ for 30 min. After cooling to room temperature, the solvent is evaporated at reduced pressure and the residue is dissolved in acetonitrile (30 ml). This solution is washed with pentane (4 • 10 ml). The solvent of the CH3CN layer is evaporated under reduced pressure, and the crude product is purified by flashcolumn chromatography (silicagel, eluant: 4 : 1 pentane-ethyl acetate) to afford a 3:1 mixture (395 mg, 68%) of the title product 274.3 and the diastereoisomeric 274.4 as a yellow syrup. This is separated into two fractions by HPLC (eluant: 70:30 hexane-tert-butyl methyl ether in 20 min to 60: 40, 16 ml/min). Eluted first is pure 274.3 (240 mg, 41%), and the following fraction contains a 2:1 mixture of 274.3 and 274.4 (155 mg, 27%). A n a d d i t i o n a l radical s y n t h e s i s 44~ o f K d o is b a s e d on t h e fact t h a t a l k y l c o b a l o x i m e c o m p l e x e s can act as radical p r e c u r s o r s b e c a u s e i r r a d i a t i o n

O AcO[XxOAc~I/'IOAc

H\

~

Sn(C4H9)3

14/

~CO2C4H9_ t

t'C4H902C /a C--C

,

AI BN toluene, 80~

274.2

o

O~AcACO~ AcO

274.1

,.

274.3

AcO

OAc

OAc 274.4

1

CH2 H R = C-~ CO2C4Ho-t

FIGURE

1.274

344

I

A S C E N D I N G SYNTHESIS OF M O N O S A C C H A R I D E S

cleaves the cobalt-carbon bond homolytically (Fig. 1.275). The a-glycosyl cobaloximes (275.1), obtained under reductive conditions, can be isomerized into the fl-derivatives (275.2), and these isomerization reactions occur via radicals which can be trapped by alkenes (275.3) or other compounds. Such reactions then give rise to addition and/or substitution p r o d u c t s 44~

(275.4 and 275.5). In the Kdo synthesis reported by Branchaud 439 NaCol(dmg)zpy is applied, and the strategic reaction is a C - - C bond construction at C-6 of Dmannose via photochemically induced radical cross-coupling of an alkylcobaloxime derivative of D-mannose (276.1) with a-ethoxyacrylonitrile (276.2) without protection of the saccharide hydroxyl groups, as shown in Figure 1.276. Bis-(dimethylglyoximato) (pyridine) (benzyl 6-deoxy-a-o-mannopyranosid-6-yl)cobalt (276.1) In a 25-ml round-bottomed flask equipped with a magnetic stirring bar and a rubber septum, a suspension of CoC16 • H20 (238 rag, 1 mmol) and dmgH2 (239 mg, 2.06 mmol) in methanol (5 ml) is deoxygenated by bubbling nitrogen through a syringe needle for 5 min. It is then treated with 50% aqueous NaOH (167 mg, 2.09 mmol) and pyridine (82/xl, 80 mg, 1 mmol). The dark-brown suspension is deoxygenated for an additional 5 min, and sodium borohydride (39 mg, 1 mmol) is added. The resulting dark-blue mixture is stirred for 5 min, and then a deoxygenated solution of benzyl 6-deoxy-6-iodo-a-D-mannopyranoside (285 mg, 0.78 mmol) in 3 ml of deoxygenated methanol is added via cannula, and the cannula is rinsed into the reaction mixture with an additional 2 ml of deoxygenated methanol. The mixture is reduced, again, with sodium borohydride (30 mg) and then stirred for 3 h; then the septum cap is removed, the mixture is diluted with acetone (10 ml), and a few grams of silicagel are added. The solvents are removed under diminished pressure to leave a free-flowing powder, which is placed on the top of 2 cm of silicagel in a fritted-glass funnel and filtered with 4:1 ethyl acetate-acetone. The filtrate is evaporated to leave the title product 276.1 as a glassy orange solid (0.44 g, 94%).

General information on photolyses is as follows. All photolyses were conducted with a 20-mmol RCo(dmgH)zpy concentration and an alkene concentration of 400 mmol in 95% ethanol. Photolyses were performed in Pyrex tubes fitted with rubber septa and equipped with magnetic stirring bars. The reaction mixtures were deoxygenated by bubbling argon gas through the mixtures for i min/ml of the mixture, and were maintained under a positive pressure of argon by means of syringe needles inserted through the septa. The argon gas was deoxygenated by passage through a heated column of BASF catalyst R3-11 in the black (reduced) form. The light sources were 300 W Sylvania incandescent floodlamps mounted in ceramic sockets and positioned 5 cm from a 800-ml beaker of water containing an immersed coil of copper tubing (10 cm diameter, 4 turns). The water bath was stirred magnetically and tap water flowing through the copper coil was used to maintain the temperature of the bath at 15-20~ The entire apparatus wrapped in aluminum foil, and a stream of air was directed over the lightbulb from the back to cool the bulb. The reactions were monitored by TLC by removing a 1-drop sample of the anaerobic reaction mixture with a long syringe needle. Preparation of benzyl 6,7-dideoxy-8-ethyl-a-~manno-non-7-enopyranosidurononitrile (276.3) 439 A solution of 276.1 (0.444 g, 0.71 mmol) and a-ethoxyacryloni-

1.2. BUILDUPOF SUGARSWITH ASCENDINGSYNTHESIS O--H ....0

/~\

i;

/ hv

R"

O--H ....O

\

N~ ~ o / N ~ "

+

N ~ I ~N/~

\P,/ O ....H--O

O ....H--O R = Co(dmgH)2py

j_%c

o~ NaBH4

[Co II (dmgH)2py]2

CH3OH

RI2 Br

AcO

= .

I~ACRI~_

AcO

12C~ 275.1

R 1 = H, R 2 = OAc R 1 = OAc, R 2 = H

o~

hv, C6H 6

Aco ~2~ Y Z

275.4 +

Y / H2C--C k z (R 1 = OAc, R2 = H)

c

I y%c ~-~~-

~176

cO ~ 2

275.3 AcO

RI2 ~ Y Z

O•Ac~j

275.5

~

O C~

AcO

Ri2

275.2 FIGURE 1.275

345

346

I

ASCENDING SYNTHESIS OF MONOSACCHARIDES 02H50

H2CCo(dmgH)2Py 0 HO " - - - - "

276.1

+ OBn

\

/ H

hv

C:C uN

95% EtOH

276.2 FIGURE

H C=C

1.276

276.3

trile (1.36 g, 14 mmol) in 95% ethanol (35 ml) is deoxygenated by bubbling argon through the solution for 30 min, and then photolyzed for 74 h. The reaction mixture is rinsed into a round-bottomed flask with acetone, and a few grams of silicagel is added. The solvents are evaporated under reduced pressure, and the resulting powder is placed on top of a 3-cm pad of silicagel in a flitted-glass funnel, and suction-filtered with ethyl acetate. The filtrate is evaporated, and the residue is purified by means of preparative TLC (eluant: 3:2 hexane-n-butanol) to give 276.3 (0.2 g, 81%), as a syrupy unseparable mixture of isomers.

Thoma and Giese 441 have also applied cyclopentadienyl dicarbonyl iron 442 [CpFe(CO)2] for generating saccharide radicals and have synthesized 443 methylene-bridged C-disaccharides. An efficient single-electron-transfer system ( S m I z - T H F - H M P A ) permits a SmIz-mediated coupling 444 of the halide and the carbonyl compound (ketone or aldehyde) in the so-called Barbier reaction. In both of the two proposed reaction mechanisms 445 the halide is supposedly reduced by SmI2, and the subsequent steps are as summarized in Figure 1.277. Sinay has postulated 446 that the reactive transient intermediate in this reaction is a chiral anomeric organosamarium(III) species. The process can also be readily executed with glycosyl sulfones, but the stereochemical outcome is different from that observed for glycosyl halides. Experimental details on the reductive samariation of 3,4,6-tri-O-benzyl-2-deoxy-c~-Darabino-hexopyranosyl chloride (277.1) are as follows. Preparation of 1-(3,4,6-tri-O-benzyl-2-deoxy-o~- and ~-D-arabino-hexopyranosyl) cyclopentanol (277.2 and 277.3) A solution of 3,4,6-tri-O-benzyl-c~-D-arabinohexopyranosyl chloride (277.1, 500 mg, 1.1 mmol) and cyclopentanone (2 eq, 195/xl) in dry THF is added dropwise at room temperature under argon to a mixture of a 0.1 M solution of samarium diiodide in THF (3 eq, 33 ml) and HMPA (5% vol, 1.65 ml). The solution is stirred until turning brown-yellow and the progress of the reaction is monitored by TLC (2:1 cyclohexane-ethyl acetate). Following dropwise addition of saturated aqueous ammonium chloride, the reaction mixture is extracted twice with ether. The organic layer is dried (MgSO4), concentrated and purified by means of flash column chromatography (eluant: 5:1 cyclohexane-ethyl acetate) to furnish, successively, 1,5-anhydro-3,4,6-tri-O-benzyl-2-deoxy-D-arabinohexitol (4.1 mg, 1%) and the target o~-anomeric sugar 277.2 (385 mg, 70%), [a]D -5.4 (c - 1.07 in chloroform). The next product to be eluted is the respective /3-anomer 277.3 (95 mg, 17%), [a]D +27 (C = 1.07 in chloroform).

1.2. B U I L D U P OF SUGARS W I T H " S a m a r i u m Barbier" mechanism R--X

+ Sml 2

+ Sml 2

347

" S a m a r i u m Grignard" m e c h a n i s m

R ~ + Sml2X

R--X

+

Sml 2

~

R ~ + Sml2X 2

~-

R1 \e C--OSml 2

R~

+

Sml 2

~-

R--Sml 2

R 89

R2

R1 \o

R1

C--OSml 2 +

R1

/

R"

R--Sml 2 *

= R2---C--OSml2

R~

I R

)

'c=o

R~

,~____OBn

BnO

SYNTHESIS

~..

R1 ~C=O

ASCENDING

R1

/

~ R2---C--OSml2 I R

,~Bn

+

20~

THe,

).

Cl

BnO

277.1

+ CSm,,

-

~

Sml 2

277.2

277.3

F I G U R E 1.277

1.2.7.11. Ascending Syntheses with Sulfonic Acid Esters Growing interest has been devoted to saccharide sulfonic acid esters in ascending procedures, and this is clearly because of the widespread application of trifluoromethanesulfonate esters (triflates). 447 For the chain extension of primary triflates, Berkowitz 448 worked out a method and observed that treatment of methyl 4-O-benzyl-2,3-di-O-methoxymethyl-6O-trifluoromethanesulfonyl-c~-D-glucopyranoside or 3-O-benzyl-l,2-Oisopropylidene-5-O-trifluoromethanesulfonyl-c~-D-ribofuranoside with a variety of functionalized C-nucleophiles in THF/HMPA leads to the corresponding chain-extended sugars in good yields. A scheme for these transformations, reported by American chemists, 448is shown in Figure 1.278 with the note that Fleet eta/. 449 previously described the successful

348

I

ASCENDING

SYNTHESIS OF M O N O S A C C H A R I D E S

R--CH2OSO2CF3

R=

+

BuLi or LDA

Nu-H

-78. ~ C

,0 OMOM Bn

CHa OMOM

n

CH3 CH3

R--CH~Nu

Null = CH3P(O)(OC2H5)2 BzNH-CH2P(O)(OC2H5)2 BzNH-CH2CO2CH3 CH3SO2C6H5 CH3CN CH3CO2C4H9-t (OH3)3si-c_=cH

F I G U R E 1.278

chain e x t e n s i o n of 4 , 5 - a n h y d r o - l - a z i d o - l - d e o x y - 2 , 3 - O - i s o p r o p y l i d e n e - 6 - O t r i f l u o r o m e t h a n e s u l f o n y l - D - t a l i t o l with tert-butyl lithioacetate. T h e n e x t e x p e r i m e n t a l p r o c e d u r e , w h e r e the C - n u c l e o p h i l e e m p l o y e d is acetonitrile, can be g e n e r a l l y a p p l i e d 448 for r e l a t e d chain extensions.

Typical triflate displacement procedure 448 All solutions were deoxygenated by freezing (liquid nitrogen) and being subjected to five cycles of evacuation and purging with argon. To a solution of disopropylamine (216 /xl, 1.55 mmol) and HMPA (268/zl, 1.55 mmol) in THF (2 ml) at -78~ is added n-butyllithium (97/xl of a 1.6 M solution in hexane, 1.55 mmol). The reaction mixture is stirred at 0~ for 30 min, cooled to -78~ and a cooled (-78~ solution of dry acetonitrile (82 ml, 1.55 mmol) in THF (1 ml) and then, 2 min later, a cooled (-78~ solution of 3- O-benzyl-l,2- O-isopropylidene-5- O-trifluoromethanesulfonyl-a-D-ribofuranoside (180 mg, 0.436 mmol) in THF (2 ml) are added via a cannula. After 10 min at -78~ the reaction is quenched [NH4C1 (aqueous 3 ml/Et20 (3 ml)], the aqueous layer is extracted with ethyl acetate (2 • 15 ml) and the combined extracts dried (MgSO4). Flash column chromatography (eluant: 30% ethyl acetate in hexane) gives 110 mg (83%) of pure 3,6-anhydro-4-O-benzyl-5,6-O-isopropylidene-L-ribo-heptononitrile. In an a d d i t i o n a l p r o c e d u r e , r e p o r t e d by Bartlett, 45~the p r i m a r y t o s y l a t e

279.1 is t r a n s f o r m e d to the a c e t y l e n e - s u g a r 279.2, which is t h e n s u b j e c t e d to a f u r t h e r o n e - c a r b o n chain e x t e n s i o n with f o r m a l d e h y d e to result in the d e c - 8 - y n o - l , 4 - f u r a n o s e 279.3 (Fig. 1.279).

O _ ~ OT~

CH20 C6Hs,,~L~O O ~ HO--_--OUI~06H5,,~.L~o ~ H or.~CH3 ' DMSO,10~ H or.~._CH3 BuLi,-78~ OH3 OH3 279.1

O__[-C----C--CH2OH

O._J--C=cH

279.2

F I G U R E 1.279

H

O~.O_.~CH3 OH3 279.3


:349

3,5-O - (R) - Ben z y lidene-6, 7,8, 9-tetradeoxy- l ,2-O-isop rop y lidene-a- D-gluco-no n8-yno-l,4-furanose (279.2) 45o To a dry round-bottomed flask are placed 1.92 g (18.8 mmol) of lithium acetylide-ethylenediamine complex and 9 ml of dry MezSO under inert atmosphere. The slurry is stirred for 15 min at room temperature, then cooled to 10~ and the tosylate 279.1 (4.47 g, 9.38 mmol), in 14 ml of Me=SO, is added dropwise over 5 min. After stirring at 10~ for 30, min the reaction mixture is partitioned between water and 50 ml of dichloromethane. The organic layer is washed with 1 N HC1 and saturated aqueous NaHCO3 (150 ml each) and worked up to afford a yellow syrup. Chromatography of the crude product (eluant: 1:5 ethyl acetate-hexane) furnished 2.96 g (96%) of pure 279.2, as a clear slightly yellow syrup, [a]2D4 +96 (C = 1 in chloroform). 3,5-0- (R) - B en z y lidene-6, 7,8,9-tetradeoxy-l ,2-O-isop rop y tidene-a- D-gluco-dec8-yno-l,4-furanose (279.3) 45o An oven-dried, three-necked round-bottomed flask is charged with a solution of the acetylene sugar 279.2 (1.36 g, 4.12 mmol) in dry THF (5.5 ml), and n-butyllithium (3.64 ml, 1.70 M solution in hexane) is added at -78~ over 3 min under inert atmosphere. The reaction mixture is stirred for 15 min before the addition of formaldehyde. The formaldehyde gas inlet consists of a Pasteur pipette connected to a T-tube on a one-necked 50-ml round-bottomed flask in which 1.86 g (61.8 mmol) of dry paraformaldehyde is placed. The paraformaldehyde is cracked using a heat gun and bubbled into the brown acetylide solution at -78~ with the aid of a stream of nitrogen gas. The reaction mixture is quenched after 10 min with saturated aqueous NH4C1, concentrated, partitioned between chloroform (150 ml) and water (200 ml), and worked up. The crude product (1.65 g) is purified by chromatography (eluant: 1:3 ethyl acetate-hexane) to furnish 199 mg (15%) of recovered starting sugar 279.2 and 1.14 g (77%) of the title propargyl alcohol 279.3 as a pale-yellow syrup, [a]2D4 +52 (C = 0.5 in chloroform).

In simple cases the conventional tosyl esters can also be employed (see Section 1.2.2), and for enhancing the effectiveness of the chain extension, bromide ions are added to the reaction mixture, such as in the conversion of 3,4-di-O-acetyl-6-O-(p-tolylsulfonyl)-D-glucal with sodium cyanide. 45] 3,4-Di-O-acetyl-6-cyano-6-deoxy-D-gluca1451 A mixture of 3,4-di-O-acetyl-6-O(p-tolylsulfonyl)-D-glucal (0.324 g, 0.842 mmol), powdered sodium cyanide (0.109 g, 2.6 eq) and tetrabutyammonium bromide (0.545 g, 2.0 eq) in acetonitrile (3 ml) is refluxed at 83~ (bath temperature) for 24 h. After cooling, the mixture is poured onto ice water (50 ml) and extracted with ether (3 • 50 ml). The combined organic layer is washed with water and brine, and then dried over MgSO4. Evaporation of the solvent and purification of the residual red-orange syrup (120 mg, 60%) by chromatography (eluant: 10% ethyl acetate in pentane)gives 40% of the pure title product, Rf = 0.61 in 7:3 toluene-ethyl acetate. I n t r a m o l e c u l a r a l k y l a t i o n i n v o l v i n g a p - t o l u e n e s u l f o n a t e f u n c t i o n is e m p l o y e d f o r t h e c o n s t r u c t i o n of c e r t a i n c o n s t i t u e n t s o f o c t o s y l i c acids. T h e a s c e n d i n g s t e p o f o n e of t h e r e l a t e d p r o c e d u r e s 452 is s h o w n in F i g u r e 1.280. 3, 7-Anhydro- 7-bis-(C-ethoxycarbonyl)-6-deoxy-l ,2-O-isopropylidene-a-Dalloheptose (280.2) and 5,6-anhydro-3-O-bis-(ethoxycarbonyOmethyl-l,2-O-isopropylidene-a-D-allofuranose (280,3) 452 A solution of 3-O-bis(ethoxycarbonyl)methyl-l,2-O-isopropylidene-6-O-(p-toluenesulfonyl)-a-D-allofuranose (280.1, 0.7 g, 1.3 mmol) in dry THF (20 ml) is cooled to -15~ and sodium hydride (34 mg, 1.4 mmol) is added. After stirring for 24 h the mixture is cooled, again, to -15~

350

i

HO_~

ASCENDING SYNTHESIS OF MONOSACCHARIDES O

OT~

O

NaH

-"~O]O~~CH3 CH3

THF, 20~

OH 3 CH3 CH(CO2C2Hs) 2

CH 3

CH(CO2C2H5) 2

280.3

280.2

280.1

O

FIGURE 1.280

and quenched by the addition of ethanol and acetic acid (lml each). The mixture is evaporated, and the residue is taken up with ethyl acetate and purified by means of column chromatography (eluant: 4:1 ~ 1:1 benzene-ethyl acetate). Eluted first is the 3,7-anhydro drivative 280.2, followed by the less polar epoxide 280.3. Intramolecular ring closure of a methanesulfonic ester derivative (the so-called Williams reaction) has been employed in a total synthesis 453 of octosylic acid A from a nucleoside, as shown in Figure 1.281. Saccharide sulfonic esters are also used as educts in oxidatively induced carbonyl-insertion reactions (ligandum-transfer reaction). 454 First, the substitution product is derived from the sulphonate with sodium dicarbonylpentahaptocyclopentadienyliron {Na § [FeCp(CO)2]-}, followed by treatment with an alcohol and an oxidizing agent to result in the oxidative incorporation: the produced [R-FeCp(CO)2] § transforms into the cationic acyliron complex [ R - C O - F e C p ( C O ) ] § a reactive species to split into an ester on the attack of the alcohol. In the carbohydrate field this methodology has been employed by Baer et al.455'456 to synthesize uronates from sulfonate esters. The oxidative insertion was effected with copper(I) chloride or with bromine, but other halogen derivatives were found to be useful as well, and the uronates prepared 455,456 using this method are summarized in Table 1.46.

foo2cH3HN O

O

1, stannylation

~

~CO2CH7,, OH

O

OBn

2, CsF, CH3OH-DMF, v

+Ioo2cH3HN

..

O

O

60"C, 8 h, 77%

Methyl 3,7-anhydro-1,6-dideoxy-l-[5-(methoxycarbonyl)3,4-dihydro-2,4-dioxo-1(2H)-pyrimydinyl]-5-O-benzylD-glycero-I}-D-allo-octofuronuronate

FIGURE 1.281

TABLE 1.46 Chain Elongation with Oxidative Insertion of Uronic Acids Starting from 6-O-Tosyl- and 6-Halogeno-6-deoxyhexoses

Educt

Product

OH Br o BzO

i~O/--CH2CO2CH3 ~ o

O

OH

H '~

OH3

BzO

r%

I~'?CHZ~

Bzo "---[ OCH~ OCH3

/ o

~z BzO

zO\

I/1 OCH3

o~~~

/

t",,,~ BzO -

BzO\

I

i,4 - OCH3

J--Bro

I OBz

OAc BzO~'N~AI ?OCH3 OAc

-135.6 (c = 0.7)

131.5

-69 (c = 0.75)

--

-13.2 (c = 1.5)

71

7 /

80

I

/L---O OCH3 ~,,~CH37

F-Br

Bzo

136.5-138

OH

BzO

J-----O OCH3 ~OBz 7

75

r---CH2CO2CH3

r---Br

OCH3

+62.1 (c : 0.7)

r-C,-,~cop.,3

Bzo

i~CH~t7

--

_ /_ L - - O OCH3

/)---O OCH3

BzO

85

I OAc

~'OH |N!

OH

+ 124.9 (c = 3.5)

r-CH~CO~C.~

O OCH3

Bzo

154-155.5

- ! - - - O OCH3 BzO

o~~,.-

70

yc;coc.

~OAc 7

I OAc

[a]o (CHCI3)

azO "---[ OCH~ OCH3

O OCH3

BzO

M.p. (~

(6OH 3 OH

r C"oC

I~?CHZ~

Yield (%)

F-CH2CO2CH3

/OBz 'Nl J"--- O/"q ,., - -OCH3 BzO ! OBz . )I--. CH2CO2CH30 ~.NIOAC//~c~ BzO ivCH 3 OAc

79

--

+37.5 (c = 1.6)

88

99-101

+56.3 (c = 0.9)

86

75-95

+ 112 (c = 0.5)

46

167-168-12

IA,~:S I i-- F 0:20020H3-'i

coOo, L0oo,c A OAc

IA

j__o;s

OAc

OAc

2

AcOK"~Ac?OOH3

-48.9 (c = 1.5)

90

! OCH3

2

AcO~ 7 " ~ . ((3 - - CH3 OAc

(c : 0.7)

352

I

ASCENDING SYNTHESIS OF HONOSACCHARIDES

Experimental details on this 'qroncarbonyl" method are given by the example of the chain extension 456 of 6,6'-di-O-tosyl-a,a-trehalose hexaacetate. Methyl [(methyl 2,3,4-tri-O-acetyl-6-deoxy-a-o-gluco-heptopyranosyluronate)2,3,4-tri-O-acetyl-6-deoxy-a-o-gluco-heptopyranoside]uronate 456 A solution of sodium dicarbonyl-r/5-cyclopentadienyliron (NaFp) [prepared from 1.065 g of Fe(CO)2Cp dimer and sodium amalgam from 6 ml of Hg and 1.5 g of Na] in oxolane (200 ml) is added under anhydrous conditions to 6,6'-di-O-tosyl-a,a-trehalose hexaacetate (2.025 g, 2.25 mmol) under nitrogen. The sugar dissolved on stirring and after 1.5 h, is completely consumed (TLC in 2 : 1 ethyl acetate.-hexane) and a strong, faster-moving yellow spot is seen prior to spraying (sulfuric acid). A stream of CO is passed through the solution at 0~ and absolute methanol (350 ml) is added, followed by bromine (2.1 ml). TLC reveals the reaction to be complete after 0.5 h;: the yellow spot (visible without spraying) is replaced by a strong spot (Rf = 0.6) of the title product, accompanied by faster- and slower-moving spots of by-products (visible after spraying and heating). The reaction mixture is concentrated to a small volume, diluted with ethyl acetate; washed sequentially with aqueous Na2S203, aqueous NaHCO3, and water; dried (MgSO4), and concentrated. The resulting brown syrup is dissolved in ether and precipitated with light petroleum (b.p. 3560~ The supernatant solvent is decanted and column chromatography (eluant: 1:1 ethyl acetate-hexane) of the syrupy precipitate gives the pure title compound (620 mg, 42%), m.p. 135-137~ [a]D +146 (c = 0.6 in chloroform).

As shown by the data in Table 1.46, the free uronic acid can be obtained when the oxidative-insertion process is performed in an aqueous medium.455, 456

1.2.7.12. Ascending Syntheses with Nitrogen-Containing Saccharides Peseke 457 has demonstrated that monosaccharides carrying a nitromethyl group are suitable materials for chain extension. Thus, as shown in Figure 1.282, the reaction of methyl 2,3,4-tri-O-acetyl-6-deoxy-6-nitro-a-Dglucopyranoside (282.1a) and 3,4,5,7-tetra-O-acetyl-2,6-anhydro-l-deoxy-

RCH2NO2

+

CS2

1, Nail 2, C"31H "=

02 SCH 3 /

R--C:C

SCH 3 282.2a

282.1

282.2b

Aoo

R= OAc 282.1a

OAc 282.!b

FIGURE 1.282

353


1-nitro-D-glycero-D-manno-heptitol (282.1b) with carbon disulfide, methyl iodide, and sodium hydride gave methyl 2,3,4-tri-O-acetyl-6,7-dideoxy-7,7bis(methylthio)-6-nitro-a-D-gluco-hept-6-enopyranoside (282.2a) and 4,5,6,8-tetra- O-acetyl-3,7-anhydro-2-deoxy-2-nitro-D-glycero-L-manno-oct1-enose dimethyl dithioacetal (282.2b), respectively. The simple experimental procedure 457 for deriving the chain-extended 6-nitrosugar 282.2a is as follows. Methyl 2,3,4-tri-O-acetyl-6, 7-dideoxy-7, 7-bis-(methylthio)-6-nitro-c~-o-gluco-hept-6eno-pyranoside (282.2a) 457 To a well-stirred suspension of sodium hydride (0.48 g, 20 mmol) in THF (50 ml), under argon, is added the methyl glycoside 282.1a (3.5 g, 10 mmol). The mixture is stirred for 2 h, carbon disulfide (1.2 ml, 20 mmol) and methyl iodide (3 ml, 48 mmol) are added dropwise with stirring, and this mixture is then boiled under reflux for lh. After being poured onto crushed ice (500 g) and extraction with chloroform (3 x 100 ml), the combined extract is washed with water (3 x 100 ml), dried (MgSO4), and concentrated under reduced pressure. The residue is crystallized from ethanol to give 2.26 g (50%) of 282a as yellow crystals, m.p. 140-141~ [~]~ - 2 9 (c = 1.0 in chloroform).

The key intermediate of a synthesis of N-acetylneuraminic acid (and its C-4-epi, derivative) described by Baumberger and Vasella, 458 is a 4,6O-acetal (283.1) of 1,2-di-deoxy-l-nitro-D-mannopyranose, and the key step is its DBU-catalyzed Michael addition to tert-butyl 2-(bromomethyl)prop2-enoate (283.2) as shown in Figure 1.283. Then careful hydrolysis of the nitro group, followed by reduction, ozonolysis, and acetal cleavage led to N-acetylneuraminic acid and its C-4 epimer. The preparation of the tert-

H

Ph

.~

~.~ 0~\

N,O~ 11o

BE

L

/CO2Bu-t

NO2 283.1

Ph

H . ~

I,,

o//,._\

283.2

H

NHAc

loH

o'.

co u-t

0

!1

HO.

~

NHAc

-

283.3

ol. 283.4

FIGURE

1,283

CO2Bu-t

II


:354

b u t y l n o n u l o s o n a t e s 283.3 a n d 283.4 was c a r r i e d o u t using t h e following proc e d u r e . 4s8 te rt-B uty l 5-acetamido- 7,9-O-ben z y lidene-2,3,5-trideoxy-2-meth y lidene- ~ mann o-4-nonulosonate (283.3) and tert-butyl 5-acetamido-7,9-O-benzylidene-2,3,5-trideoxy2-methylidene-D-manno-4-nonulopyranosonate (283,4) 458 To a stirred, cold (0~

solution of 2-acetamido-4,6-O-benzylidene-l,2-dideoxy-l-nitro-D-mannopyranose (283.1, 8.4 g, 24.8 mmol) and tert-butyl 2-(bromomethyl)prop-2-enoate (283.2, 8.4 g, 37.2 mmol) in THF (75 ml) is added, dropwise, a solution of DBU (8.4 g, 49.6 mmol) in 25 ml of THF over a period of 4 h. Stirring is continued at the same temperature for 20 h, then the precipitate is filtered off and the filtrate is diluted with 200 ml of ethyl acetate. The usual workup, involving extraction with water and brine, yields the crude product (13.1 g), which is taken up in a mixture of THF (80 ml) and 20 ml of a pH-6.6 phosphate buffer, and then treated with urea (1.95 g, 27.3 mmol). The resulting mixture is stirred at room temperature for 3 days, diluted with ethyl acetate (100 ml), and washed with 5% aqueous NaHCO3, water, and brine to give a yellow syrup, which is dissolved in a 1:1 ethyl acetate-ether mixture. Addition of hexane gives a precipitate, which is filtered off and crystallized from ethyl acetate-ether-hexane affording slightly yellow crystals of 283.3 and 283.4 (2.2 g). Fast column chromatography of the combined mother liquor on silicagel (500 g; eluant: 97:3 dichloromethane-methanol) gives an additional crop (5.0 g, 64%) of 283.3 and 283.4, m.p. 143-144~ [c~]~ +20.5 (c = 1.0 in MezSO). F u r t h e r c h a i n e x t e n s i o n s with M i c h a e l a d d i t i o n w e r e c a r r i e d o u t between 1-deoxy-2,3- O-isopropylidene-l-nitro-5-O-pivaloyl-/3-D-ribofuranose (284.1) a n d acrylonitrile or m e t h y l p r o p y n o a t e . In b o t h cases t h e / 3 - a n o m e r i c n i t r o a l d o s e s (284.2 a n d 284.4) p r e d o m i n a t e d in t h e a n o m e r i c m i x t u r e s p r o d u c e d in t h e r e a c t i o n (Fig. 1.284), i n d i c a t i n g a p r e f e r r e d e n d o - a t t a c k o n t h e n i t r o n a t e a n i o n d e r i v e d f r o m t h e educt, 459 a n d this was also s u b s t a n t i a t e d by A M 1 calculations. T h e a s c e n d i n g step w i t h m e t h y l p r o p y n o a t e c o u l d b e e x e c u t e d u n d e r e x c e p t i o n a l l y m i l d c o n d i t i o n s (at - 3 0 ~ as d e s c r i b e d in t h e f o l l o w i n g e x p e r i m e n t a l p r o c e d u r e . 459

P i v O ~ PivO~o.~O2

= CH^=CH-CN ~

O O

+ CN

O O

HaC/V~CH3

HaC~CH3

284.2 I

284.3

I

O O H3CXCH3

+

284.1

O O 0020H3 H3CXCH3 284.4

FIGURE 1.284

CN

PiVO~No2

CO2CH3

PivO-~o~ -J NO2 O O H3C'~CH3 284.5


355

Methyl (E)-2,3,5-trideoxy-5,6-O-isopropylidene-4-nitro-8-O-pivaloyl-~- and a-ooct-2-en-4-ulofuranosonate (284.4 and 284.5) 459 A solution of the 1-nitrosugar 284.1 (6 g, 19.78 mmol) in dichloromethane (20 ml) is treated at -30~ with triethylamine (8.28 ml, 59.4 mmol). Then a solution of methyl propynoate (1.82 ml, 21.78 mmol) in dichloromethane (20 ml) is added dropwise over 30 min. The reaction mixture is stirred for 30 rain at -30~ allowed to warm to room temperature, and worked up. Chromatographic purification (eluant: 1:3 ether-hexane) gives 3.67 g (48%) of 284.4, as a syrup, [a]D --128 (C = 0.1 in chloroform), Rf = 0.46 (1:1 ether-hexane), and 1.83 g (24%) of 284.5, m.p. 69-70~ [C~]D --33 (C = 0.63 in chloroform), Rf = 0.39 (1:1 ether-hexane).

As reported by the Vasella group, glycosylidene carbenes--available from diaziridines 46~ via diazirines (also called 1-deoxyhydrazi- and 1-azi-l-deoxyglycoses)--are versatile nitrogen-containing saccharide derivatives 461 for syntheses, including chain extensions. Diazirines are prepared from aldonhydroximolactones (285.2) available from aldose oximes (285.1) by dehydrogenation 46~(Fig. 1.285). On thermolysis, diazirines (285.3) are transformed into glycosylcarbenes (285.4). The first representative reactions of these reactive species (among others, with hydroquinone monomethyl ether) have s h o w n 462 that formation of an O-glycoside is expectedly preferential. Thus, from 1-azi-2,3,4,6-tetra-Obenzyl-l-deoxy-o-glucopyranoside, 69% of 4'-methoxyphenyl 2,3,4,6tetra-O-benzyl-a,fl-D-glucopyranoside w a s p r o d u c e d 462 together with 16% of a mixture of (1S)- and (1R)-l,5-anhydro-2,3,4,6-tetra-O-benzyl-l-C(2'-hydroxy-5' -me th oxyph e nyl)- D-glucit O1. Glycosylidene carbenes are expected to be ambiphilic-nucleophilic, and to form spirocyclopropanes by cycloaddition to acceptor-substituted alkenes. Descotes and Praly have s h o w n 463 that photolysis of O-acetylated glycopyranosylidene-l,l-diazides (286.1) in the presence of acrylonitrile

r~ O~

N'.,-OH

~

~

[O] "

~N~OH R2

285.1

R3SO2C1

........

~--

N--O--SO2 R3 R"

285.2

I NH

r~

~

Q

V~ " '2'E'3N V~ R2

R~1~2

285.4

285.3 FIGURE

1.285

NH

356

~ ASCENDING SYNTHESlS OF MONOSACCHARIDES

X~

OAc N3

Ac AcO

hv

I

I N3 OAc

286.1

r---OAc

"~.~ c ob,l

X = electron acceptor

FIGURE

R1

I/",L,,R~ ~R"

OAc

286.2

1.286

leads to a mixture of the diastereoisomeric spirocyclopropanes 286.2 (Fig. 1.286). Mixtures of isomeric spirocyclopropanes can also be obtained 464 in good yields by thermolysis of O-benzylated glycosylidene-diaziridines in the presence of N-phenylmaleimide, acrylonitrile, dimethyl fumarate, or dimethyl maleate (Fig. 1.287). Preparation of the glycosylidene-carbene from 1-hydrazi-2,3,4,6-tetra-O-benzyl-l-deoxy-D-glucopyranose, and its chain extension with acrylonitrile are given 46~ in the following procedures. 1-Azi-2,3,4,6-tetra-O-benzyl-l-deoxy-D-glucopyranose (287,1) 460 Powdered 1-hydrazi-2,3,4,6-tetra-O-benzyl-l-deoxy-D-glucopyranose (500 mg, 0.9 mmol) is dissolved at room temperature in methanol (25 ml), and triethylamine (2 ml, 14.3 mmol) is added. The solution is cooled to -45~ and under efficient stirring a solution of iodine (230 mg, 0.9 mmol) in methanol (4.5 ml) is added dropwise (0.5 ml/min). After addition of about two-thirds of the idodine solution, 287.1 starts to precipitate. Following complete addition, the crystalline product is filtered off under nitrogen and washed with cold (-40~ methanol and then three times with hexane (at ambient temperature) to yield 458 mg (92%) of 287.1. Cyclopropanation of 287"1 with acrylonitrile 460 Acrylonitrile (3 ml, 78.5 mmol) is stirred under nitrogen in the presence of 0.5g of 4_A molecular sieves at room BnOj,----~~ 0 BnO"- \-'"~'f_..--v..._\ _.,.N BnO ~

(

B ,.;oT// N

287.1

r

CN

a)

1

l

l

1

BnO~--~s j(~^ _ ~ pro-R BnO~--X _..O H p~ R BnO,,,.---,-~~ O H BnOj...--.~. 10 BnO"~6\~.-~j.~=..~\~ BnO~ _ . . ~ \ ~.. o- BnO~ _ . . ~ \ ~ BnO~ ~ . ~ \ B nO--~"'-B n'oT/ " H p,o~ BnO--~,,-'Br~OT/ " H pro~ BnO.-~.,-~Bn'oT/ "CN BnOJBn'OT/ 287.2

NC

pro-R

287.3

287.4

a) R.t., 12 h, 287.2: 36%; 287.3: 22%; 287.4: 8%; 287.5: 4%

FIGURE

1,287

pro-RH 287.5

CN "H pro-=5

1.2. BUILDUP OF SUGARS WI'I:H ASCENDING SYNTHESIS

357

temperature for 30 min. Then, 690 mg (1.25 mmol) of 287.1 is quickly added, and the mixture is stirred at room temperature for 12 h, diluted with dichloromethane (5 ml), and filtered through Celite. The Celite is Washed several times with dichloromethane, the combined filtrate is evaporate& and the residue is subjected to fast column chromatography (eluant: 4:1 pentane:-ether) to give 506 mg (70%) of a mixture of products which were separated by a second chromatography (eluant:: 10:1 ~ 4:1 pentane-ether) to give the diastereoisomeric 6,7,8-tris-(benzyloxy)-5[(benzyloxy)methyl]-4-oxaspiro[2.5]octane-l-carbonitriles 287.2-287.5, as colorless syrups, with the following physical data (TLC in 1:1 pentane-ether). 287.2:

(1R,3R,5R,6R,7S,8R), 36%, [o~]~ +108.7 (c = 2.4 in chloroform),

287.3: 287.4: 287.5:

(1S,3R,5R,6R,7S,8R), 22%, [a]~ -2.5 (c = 2.0 in chloroform), Rf = 0.65 (1R,3S,5R,6R,7S,8R), 8%, [c~]~ +50.2 (c = 0.77 in chloroform), Rf = 0.76 (1S,3S,5R,6R,7S,8R), 4%, Rf = 0.84

Rf, = 0 . 8 6

F o r m a l l y , t h e highest carbon ~chain extension of s a c c h a r i d e s h a s b e e n p e r f o r m e d by t h e V a s e l l a g r o u p 466,467 with t h e r e a c t i o n of g l y c o s y l - c a r b e n e s with b u c k m i n s t e r f u l l e r e n e (C60) to p r o v i d e s p h e r i c a l ( a n d n o t o p e n - c h a i n ) p r o d u c t s (Fig. 1.288). W h e n p r e p a r i n g such f u l l e r e n e s , i n v e s t i g a t o r s h a d to focus special a t t e n t i o n on t h e r e m o v a l of t h e p r o t e c t i n g g r o u p s of t h e s a c c h a r i d e ; t h e first e x p e r i m e n t s failed with b e n z y l functions. 466 A c e t a l H3C OH3 ~l H3C"~._ v H3C

O...-

H~C

O

-

~

H3C CH3 I H3C'~ ~

CH3 "

H3C "~oO -/~""-~ tO H

- -

i, H3C/

O

OH 288.1

288.2

288.3 R " H 288.4 R = Ms

288.8

D, H3C

OR

\ OCH3 R = t-C4H 9 or CH2C6H 5

51.1

51.2

F I G U R E 2.51

and 15 ml of benzene) isboiled under reflux for 20 h. Following evaporation, the residue is taken up with benzene, and the organic solution is successively washed with 5% aqueous citric acid, water, and aqueous NaHCO3, and is then dried and evaporated. The product (51.2) is isolated by means of column chromatography (eluant: 4:1 ether-hexane) and recrystallized from a mixture of ether and hexane. Application of this procedure for two s u b s t r a t e s - - m e t h y l 2,3,4-tri-Omethyl-/3-glucuronic acid (52.1) and the corresponding gentiobiose derivative (52.2)--is shown in Figure 2.52. Descending synthesis 7 of uronic amides into tert-butylurethanes (or benzylurethanes) can also be accomplished by means of another variant of the Curtius degradation. 8,9 Figure 2.53 shows three examples for this methodology, according to the work of Aspinall et al. 7 Degradation of O-methylated uronic glycosides with lead tetraacetate7 A mixture of the permethylated uronic glycoside (1 mmol), pyridine (1 mmol), lead tetraacetate (4.5 mmol), and 15 ml of tert-butanol (or a mixture of 15 ml of benzene and 1.2 mmol of benzyl alcohol) is boiled under reflux for 4.5 h. Then an additional amount (4.5 mmol) of lead tetraacetate is added, and the reaction mixture is boiled for another 20 h. It is then concentrated, the residue is extracted with ether or ethyl acetate, and the extracts are washed with water and concentrated. Purification of the products is done by column chromatography (eluant: 4:1 ether-hexane).

2.4.3.2. Degradation of Onic and Uronic Amides with Hypochlorite Descending synthesis of the amide derivatives of onic and uronic acids can also be effected by the well-known H o f m a n n degradation with hypohalogenite ion. Shortening of the sugar chain is a result of a reaction sequence involving transformation into N - h a l o g e n o a m i d e and isocyanate. The glycosides of the uronic amides (54.1) were also subjected to these conditions (Fig. 2.54), but the primary products of the transformations could be detected only by mass spectrometry in the form of O-glycosides or O-acetyl derivatives. The products can also be identified by gas chromatography after conversion (with NaBH4 reduction) into the corresponding alditol derivatives. 1~ A similar conversion of O-methylated aldonic amides with sodium hypochlorite ( W e e r m a n degradation) also gives rise to the isocyanate,

43l

2.4. DEGRADATION OF SACCHARIDES WITH OXIDATIVE METHODS CO2H ~'

O OCH3

CH30 "~

~" OCH3 52.1

o;c

HN -- CO2CH2C6H5

CH3 CH30 ~

HN --CO2t-C4H 9 O OCH 3 CH3

1 OCH 3

CH30 "~

Methyl (5S)-5-benzyloxycarbonylamino2,3,4-tri-O-met hyl-13-D-xylopyranoside rn.p. 137~ [~]D = -14.2 (CHCI3)7 87%

~ I OCH3

Methyl (5S)-5-tert-butyloxycarbonylamino2,3,4-tri-O-m ethyl-J3-D-xylopyranoside m.p. 123.5-124.5~ [o~]D =-12.4 (CHCl3)7 87%

CO2H

NHCO2R

lOaCH3 7 O,

:

O OCH3

7

R-OH

.

OCH3

ooc

~

OCH 3

52.2

R = ted-butyl:

Methyl2,3,4-tri-O-methyl-6-O-[(5S)-5tert-butyloxycarbonylamino-2,3,4-tri-Omethyl-13-D-xylopyranosyl)-t3-D-glucopyranoside m.p. 128-130~ [oc]D =-3 (CHCl3)7 86%

R = benzyl:

Methyl 2,3,4-tri-O-methyl-6-O-[(5S)-5benzyloxycarbonylamino-2,3,4-tri-O-methylI~-D-xylopyranosyl)-13-D-glucopyranoside m.p.: 177-179~ [O~]D=-3 (CHCI3)7 92 %

FIGURE 2.52

432

2 DESCENDING SYNTHESlS OF NONOSACCHARIDES HN--CO2t-C4H9

CONH2

CHaO~ocH 3 0

CH30~OCH3 ~ O CH30__ I .

?

O

CH3

O

Pb(OAc)4 t-C4HgOH

CH30"~L__" CH30 "~

1 OCH3 Methyl 3,4-di-O-methyl-2-O-(2,3,4,6-tetra-O-methyl-I~-Dglucopyranosyl)-5-(5S)-tert-butyloxycarbonylamino13-L-arabinopyranoside m.p. 107~ [O~]D= +77 (c = 1, CHCI3) 86%

OCH3

HN--CO2t-C4H9

o O/o y

CONH2 o

AcO

I OCH3 0

OOOH

I AcO "~Ac ,~ OAc I OAc

Pb(OAc)4

OAc

t-C4H9OH

Ac

OAc

OAc Ac

O OCH3

[ OAc

Methyl 2,3,4-tri-O-acetyl-6-O-[(5S)-tert-

butyloxycarbonylamino-2,3,4-tri-O-acetyl13-O-xylopyranosyl]-13-D-glucopyranoside m.p. 132-133~ [(~]D= -12 (c = 0.3, CHCI3) 81%

CONH2 AcO ,J----- O OCH3 OAc

HN--CO2t-C4H9 AcO [ O

Pb(OAc)4

t-C4HgOH

I OCH3 OAc Methyl 2,3,4-tri-O-acetyl-(5S)-5-tert-

butyloxycarbonylamino-13-L-arabinopyranoside m.p. 184-185~ [O~]D= +139 (c= 0.17, CHCI3) 83%

FIGURE 2.53

which is transformed, again (without isolation) into either the stable urethane or the one-carbon-atom-shortened aldose by treatment with a base to induce split off of the isocyano function in form of NaOCN. The degradation also proceeds when all of the hydroxyl groups are methylated, and the products are the descended aldose, carbon dioxide, ammonia, and methanol. 11 The preceding methodology (first used as an analytic degradation procedure 12 exclusively) is quite suitable for the specific chain shortening of methylated aldonic amides. For example, Figure 2.55 shows the sodium hypochlorite-induced descending synthesis 11 of 2,3,4,5,6-penta-O-methylD-gluconyl amide (55.1).

2.4. DEGRADATION OF SACCHARIDESWITH OXIDATIVE METHODS

CONH 2

R 1 0 ~ ~ O R O OR + NaOCl

0oC

I NH20

-7

CliO

.~ R1 0 ~ ~ O RICHO + ROH+ NH4+

OR

lh

433

R1

54.1

I NaBH CH2OH R10~ CH2OH FIGURE 2.54

2,3,4,5-Tetra-O-methyl-aldehydo-D-arabinose (55.2) 11 A solution of 2,3,4,5,6penta-O-methyl-D-gluconyl amide (55.1, 1.0 g) in water (12 ml) is treated at 0~ with a standardizedNaOC1 solution13(4.9 ml). After 2 days, the mixture is acidified with HC1, neutralized with BaCO3, and evaporated to dryness. The residue (0.7 g) is completely soluble in water. The product is subjected to vacuum distillation at 1.33 Pa (bath temperature 85~ to give pure 55.2, n~ 1.4340, [a]~ 5 + 16.6 (c = 2.89 in water, no mutarotation is observed). This above descending procedure permits the isolation of the cyclic urethanes of the corresponding methoxyaminals from partially protected D-glyconic amides. Three of these products (56.2, 56.4, and 56.6), derived from the sugars 56.1, 56.3, and 56.5, are shown in Figure 2.56.11'14'15 2.4.3.3. Descending Synthesis by Decarboxylation of Mercuric and Silver Salts of Uronic Acids The long-known degradation of the mercuric and silver salts of simple carboxylic acids with iodine or bromine (Borodin-Hunsdiecker reaction) into the one-carbon-shorter alkyl or aralkyl halides 16-19 can be employed for descending synthesis of carbohydrate derivatives as well. In this radicaltype process carbon dioxide is liberated, and the first step of the transformation is heterogeneous, resulting in the cleavage of only a portion of the halogen (in the form of metal halides), which is of positive character in solution, similar to that present in the hypohalides. It is supposed that the CONH2 OCH3

H3CO 9

OCH3 OCH3 OCH3

H..c~O NaOCl 0~ 2 days

55.1

.~

H3CO...~ L--OCH3 __OCH 3

I

E

55.2

FIGURE 2.55

OCH3

434

2 DESCENDING SYNTHESIS OF MONOSACCHARIDES

---OCH

CONH 2

F

OCH NaOCI

H3CO-- 1

0oc

H3CO-- I H3CO ,#L

0

OCH

L-.--OCH 3

56.2

56.1

m.p. 110~ [ od 18 = +99.3 (c = 0.56, H 2 0 ) "D CONH 2

F

OCH 3

OCH NaOCI

H3CO--- t

b

0oc

OCH

l

H3CO

OCH 3

OCH 3 56.4

56.3

m.p. 167-168~ [OqD8 = +167.8 (c= 1.49, H20) b.p. 170~ / 1.33 kPa

oc,

CONH 2 H3CO--- ~

HO'~_.__

-

NaOCl 0~

co_oc!>

0

OCH3 H

OCH 3 56.6

56.5

m.p. 75~

FIGURE 2.56

reaction mixture contains an acylhalogenite of the type RC(O)OHal, and the reaction proceeds with a radical mechanism, as shown in Figure 2.57. By treatment of 2,3,4,5,6-penta-O-acetyl-D-gluconic acid and the corresponding acid chloride with bromine, 1-acetoxy-l-bromo-2,3,4,5-tetra-Oacetyl-D-arabinitol was obtained, which was identified in form of 1,1,2,3,4,5hexa-O-acetyl-o-arabinitol (m.p. 89-90~ [~]~ +30 (c = 2.0 in chloroform). 2~ The following procedure 22 gives an experimental prescription for the execution of the Borodin-Hunsdiecker reaction (see Fig. 2.58).

2,6-Anhydro-l-bromo-l-deoxy-3,4,5, 7-tetra-O-acetyl-D-gluco-heptitol (58,2) 22 In a dark flask, to a solution of 2-(tetra-O-acetyl-fl-o-glucopyranosyl)acetic acid

2.4. DEGRADATION OF SACCHARIDESWITH OXIDATIVE METHODS //O R--C ~O(s

-AgHa,

+ Hal2

IR_cZO

al

_CO2

~

435

R ~ + Br"

O--H

~Br2

Hal = Br

RBr + Br-

~

R C O O B r

Br2 + CO2 + R 9

~

etc.

FIGURE 2.57

(58.1, 54 mg, 0.14 mmol) in carbon tetrachloride (1 ml), yellow mercuric oxide (30 mg) and a solution of bromine (40 mg) in 1 ml of carbon tetrachloride are added, and the mixture is boiled under reflux for 3 h. The resulting suspension is placed on top of a silicagel column (2 • 20 cm), and eluted with chloroform, and the eluate is concentrated to give a crystalline residue. This is scrubbed with ethanol, and the crystals are filtered off to give 51 mg (87%) of crude 58.2. Twice recrystallizations from ethanol gives the pure target compound with m.p. 119.5-120~ [o~]~ -12.4 (c = 1.1 in chloroform). G e n e r a t i o n of the radical in the B o r o d i n - H u n s d i e c k e r d e g r a d a t i o n m a y be effected by the application of the N-hydroxypyridin-2-thione esters 59.1 by heating in b r o m o t r i c h l o r o m e t h a n e to induce " d e c a r b o x y l a t i v e halog e n a t i o n " as shown in Figure 2.59. 23.25 T h e Fleet group 26 successfully e m p l o y e d this strategy in the carbohydrate field for p r e p a r a t i o n of the f o u r - m e m b e r e d ring o x e t a n e derivatives (oxetanosides) of carbohydrates. Fleet et al.26 used this strategy to synthesize the anomeric 2-azido-4-O-(tert-butyldimethylsilyl)-2-deoxy-D-erythro-oxetanosyl chlorides (60.2) f r o m the carboxylic acids 60.1 (Fig. 2.60). A n analogous d e g r a d a t i o n of a 1:1 mixture of the sodium salts of 3,5-anhydro-l,2-O-isopropylidene-D-glucuronic- and L-iduronic acid (61.1) p r o c e e d s 27 with only a 27% overall yield via the N-hydroxypyridin-2t h i o n o e s t e r (Fig. 2.61) to give 2a the xylofuranose 61.2.

FOAc

, / - - - o \ r_C%H co-

B2,

i"

FOAc

,/----o\ r_B t"

OAc 58.1

OAc 58.2 FIGURE 2.58

436

2

DESCENDING SYNTHESIS OF MONOSACCHARIDES

//0

R--C\ O--N~

+ ~

3

A ~ 9

+ R-CO2*

"CO2 # R"

CCI3Br

R--Br

SCCl 3

S 59.1

FIGURE 2.59

Chain shortening of the mixture of the 2,4-anhydro-D-arabonic and ribonic lactones 62.1, available from 3,5-di-O-benzyl-D-ribono-l,4-1actone, also gives a separable mixture of the chain-shortened products 62.2 and 62.3, as shown in Figure 2.62. There are also reports in the literature for the preparation of 2,3,4,5tetra-O-acetyl-D-arabonic acid derivatives from the corresponding Dgluconic acid by means of a similar procedure. 29'3~

2.4.3.4. Decarboxylation of Uronic Acids with Lead Tetraacetate Contrary to the generally observed outcome 31-33 of the oxidation of hydroxycarboxylic acids with lead tetraacetate, degradation of protected uronic acids (63.1) leads to a mixture of (5R)- and (5S)-acetoxy-aldopyranoses (63.2) by replacement 34 of the r group with an acetoxy substituent (Fig. 2.63). Figure 2.64 summarizes the degradation products (64.2-64.5) obtained 35 by the lead tetraacetate oxidation of methyl 2,3,4-tri-O-methyl-/3o-glucuronate (64.1). The outcome of this process is obviously dependent on the configuration of the anomeric center; from the corresponding c~ anomer no dimers except the two 5-C-acetoxylated sugars are produced. An analogous descending synthesis of methyl 2,3,4-tri-O-methyl-/3-o-galactopyranuronic acid (65.1) and the corresponding c~ anomer (65.3) gives rise 35 exclusively to the 5-Cacetoxy sugars (65.2 and 65.4, respectively) as shown in Figure 2.65. Sometimes the C-5 epimeric products cannot be separated, as in the case 36 of the mixture (66.2, Fig. 2.66) obtained from benzyl 2-acetamido2-deoxy-3,4-di-O-benzyl-c~-o-glucopyranuronic acid (66.1). (R,S)-Benzyl 2-acetamido-5-C-(acetoxy)-3,4-di-O-benzyl-a-o-xylopyranoside (66.2)36 To a solution of the uronic acid 66.1 (8.0 g, 0.02 mol) in dry benzene (150 ml), lead tetraacetate (23 g, 0.05 mol) is added, and the mixture is boiled under reflux for 2 h. After cooling, it is diluted with ethyl acetate and extracted with water to remove inorganic salts. The organic layer is dried (MgSO4) and concentrated to a syrup. The anomeric mixture 66.2 (5.9 g, 72%) is obtained after scrubbing with hexane.

Similar oxidation of methyl 2,3,4-tri-O-benzyl-c~-D-mannopyranuronate led 37 to the C-5 epimeric methyl 5-(acetoxy)-2,3,4-tri-O-benzyl-lyxopyranosides [24% (R) and 55% (S)]. This procedure has been successfully employed

437

2.4. DEGRADATION OF SACCHARIDES WITH OXIDATIVE METHODS TBDMS--O~c

1, (COCI) 2, benzene O2H 2, N-hydroxypyriciin-2-thione Na-sali ''-~ N3 CCI4, A

TBDMS-- O - - ] ~ , ~ N3

60.1

60.2 FIGURE

;

H,.

C!

2.60

CO2Na

H

O..,...~

CC!4 +

OI---~-CH3 CH 3

Cl

O

_

HO--

L~

O---~-CH 3 CH3

61.1

61.2

3,5-anhyd ro-5R-chloro-1,2-Oisopropylidene-D-xylofuranose m.p. 62-63~ [c~]20_D_+92, (c = 1.14, CHCI3) FIGURE

9

OBn

COCI +

HO--

2.61

:> CC,

BnO--~CI

62.2

62.1

BnO--~C I

OBn

62.3

2,4-di-O-benzyl-o~-D-erythrooctanoylchloride [o~]20 = +130.2 (c = 0.9, CHCI3)

2,4-di-O-benzyl-lB-D-erythrooctanoylchloride [~] Zu = -32 (c =1.4, CHCi3) IJ

FIGURE

~O2H

0

OBn

2.62

OAc Pb(OAc) 4 benzene, A -CO2

63.1

R1

OR

63.2 FIGURE

2.63

CO2H

I

Ch30

00CH 3 1 OCH 3

64.1 Pb(OAc) 4 benzene, A

I

0

O

OAc -O

OCH 3

~~oA,c .....O OCH 3 CH30

CH30

[ OCH3

OCH 3

"'~ CH30 N

O OCH3? ' I " cH30 " OCH 3

...... O OCH 3 I OCH 3

"C

I

CH30 "~

-

0 0 C H 3 CH30~ I OCH 3

0

.......0

OCH 3

v OCH3

64.2

64.3

64.4

64.5

(R)-Methyl 5C-(acetoxy)-2,3,4-triO-methyl-13-D-xylopyranoside m.p. 50-50.5~ [o~]21 D = -12.0 (c = 1.2, CHCI 3)

(S)-Methyl 5C-(acetoxy)-2,3,4-triO-methyl-13-D-xylopyranoside m.p.-[o~]21 = -127.9 (c = 1.1, CHCI 3) D 30%

(R)-Methyl 5-[(methyl-2,3,4-tri-O-methyl~-D-glucuronoyloxy)]-2,3,4-tri-O-methylI~-D-xylopyranose m.p. 83-85~ [o~]21 = -45.0 (c = 1.3, CHCI 3) D 5%

(S)-Methyl 5-[(methyl-2,3,4-tri-O-methyl13-D-glucuronyloxy)]-2,3,4-tri-O-methyl13-D-xylopyranose m.p.-[or] 21 = -85.0 (c = 1.0, CHCI 3) D 3%

42%

F I G U R E 2.64

2.4.

DEGRADATION O F SACCHARIDES WITH OXIDATIVE METHODS

CO2H O OCH3 CH30~OCH3 / ~

C H 3 0' ~

l#'oAc

Pb(OAc)4

"N,,~CH3

A, benzene

I

/,~

00CH

439

3

I

oca 3

OCH3 65.2

65.1

(S)-Methyl 5C-(acetoxy)-2,3,4-tri-O-methyl13-L-arabinopyranoside 21 = -85.0 (c = 1.2, CHCI3) [o~1D 73% OAc

CH3?/~ O2H 0

O CH30~OCH3 / ~

Pb(OAc)4 A, benzene

J OCH3 OCH3

OCH3 65.4

65.3

(R)-Methyl 5C-(acetoxy)-2,3,4-tri-O-methylo~-L-arabinopyranoside [~ 19 = +123.7 (c = 1.2, CHCI3) 7% (82% of the starting material remains unchanged)

FIGURE 2.65

for disaccharide-uronates, 38 complex glucuronide-saponines, 39 and other p o lysaccha rides. 38 In terms of synthesis, a clear advantage of the oxidative decarboxylations is that the produced 5-C-acetoxy sugars--as masked dialdehydes-can be employed for nitromethane condensations to afford nitrocyclitols (see Section 1.2.3). On the basis of this synthetic potential, the formal synthesis of aminocyclitol antibiotics, such as kanamycin C, has been elaborated, in which the key step (Fig. 2.67) is the oxidative descending synthesis 4~ of the disaccharide 67.1 into 67.2.

CO2H Bn BnO "

)o

AcO ~.

CH2C6H5 NHAc

OBn Bn

66.1

)o

CH2C6H5 NHAc

66.2

FIGURE 2.66

440

2

DESCENDING SYNTHESIS OF M O N O S A C C H A R I D E S

;-% AcO

"

f J Z--NH O

MMTr-O~Ac f~oc.3 ,O

Pb(OAc)4

Z--NH

benzene:pyddine 3.5h reflux

?

-CO2

AcO "=

Z--NH

I///~OCH3 Z--NH

67.2

67.1

1,2-di-O-acetyl-4-deoxy-5C-methoxy-4[t(benzyloxycarbonyl)amino/-o~-D-xyiopyranosyl3-O-(3,4,6-td-O-acetyl-2-deoxy2-(benzyloxycarbonyl)amino]-~-D-glucopyranoside

Methyl 3-O-acetyl-2-deoxy-3-O-(2-deoxy-2-benzyloxy-

carbonylamino)-o~-D-(glucopyranosyl)-2[/(benzyloxycarbonyl)amino/-6-(monomethoxytrityl)]<x-D-glucopyranoside

71%

FIGURE 2.67

The preceding chain shortening strategy has also been successfully used in the synthesis 41 of ribostamycin from the trisaccharide shown in Figure 2.68. Recent studies have shown 42,43 that the descending reaction of uronic acids also proceeds at room temperature under very mild conditions. Oxidation of 1,2-O-isopropylidene-3-O-benzyl-c~-D-ribofuranuronic acid (69.1) is complete in 2.5 h at 20~ (Fig. 2.69) and gives the chain-shortened sugar 69.2. Instead of lead tetraacetate, 3-chloroperoxybenzoic acid has also been used for related oxidative degradations. For example, FigUre 2.70 shows the conversion of 2,6-anhydro-3,4,5-tri-O-benzyl-7-O-(trimethylacetyl)-Lglycero-L-gulo-heptonic acid (70.1) into the L-glucopyranose 70.2, representing an interesting entry to the rare L-sugar series. 43 Shiozaki et al.43 have reported the preparation of additional L-sugars with this methodology.

AcO ~

,,co-

o

~ k ~ ~

0

,,c

benzene,

.co

,,co-L

I

i/~0

o..j /

~-~.

OAc OAc R = CO2H

R = o~,13-OAc FIGURE 2.68

74%

,,c

441

2.4. DEGRADATION OF SACCHARIDES WITH OXIDATIVE METHODS OAc

CO2H

BnO

Pb(OAc)4 20~ 2.5h

OH3 OH3

BRO~O.~__O

OH3 OH3

69.2

69.1

[3aR(3aoq513,6o~,6ao0]-tetrahydro-2,2-dimethyl5-acetoxy-6-(phenylmethoxy)furo-[2,3-d]-l,3-dioxol m.p. 72-73~ [o~]25 = +82.3 (c = 1.03, CH3OH) 83% F I G U R E 2.69

The effect of WOC14, and that of WOC14 and a "proton sponge" have also been investigated 44 to produce enol derivatives. However, no related studies on sugars have been reported as yet.

2.4.3.5. Electrochemical Oxidation of Uronic Acids It has long been recognized that the electrolysis of D-gluconic acid leads 45 to oxidative decarboxylation instead of Kolbe-type chain extension. The voltage-controlled electrolysis of methyl 2,3,4-tri-O-methyl-/3-Dglucopyranuronic acid in the presence of methanol gave (R)- and (S)5-C-methoxy-2,3,4-tri-O-methyl-/J-D-xylopyranoside. When acetic acid was present, the corresponding 5-acetoxy derivatives were produced, and these latter compounds were identical to the products of the lead tetraacetate oxidations (see Section 2.4.3.4). Voltage-controlled electrolysis of sodium methyl 2,3,4-tri-O-methyl-~-D-glucopyranuronate 46 To a solution of the title sodium salt (0.15 g) in methanol (50 ml), NaC104 (0.5 g) is added, and this is subjected to voltage-controlled electrolysis in an open beaker at 1.72 V (saturated kalomel-electrode, potentiostat-galvanostat equipment, Hokutu Denko Co. Model HA-105). Then the solvent is distilled off,

O~.c.,O-OH

CO2H I

CI

o ~H3 O--C--C--OH

I

CH 3

OBn

3

"

DCC, CH2CI2 -CO2

,~--O Bno~Bn

o

r----O--C--C--OH3 /~

CIH3

I

OBn 70.2

70.1

[o~]~" =

F I G U R E 2.70

+32 (c = 0.9, CHCI3)

34%

'

442

2


water is added to the residue, and the product is extracted with ethyl acetate. The organic phase is dried over MgSO4 and evapoated to a syrup, which is purified by means of preparative layer chromatography (running system: 1:1 hexane-ethyl acetate) to obtain 91 mg (63%) of (SS)-methyl-5-C-methoxy-2,3,4-tri-O-methyl-BD-xylopyranoside, [c~]~ -109.7 (c = 10.2 in chloroform), and 47 mg (33%) of the (5R)-epimer, [a]ff __0 (c = 5.0 in chloroform). The obvious advantage of the electrolytic oxidation is that descending synthesis can be effected without introduction of protecting groups, so that the methyl glycoside of the dialdehyde is suitable for a direct, further derivatization. From o-glucuronic acid (71.1), an unstable product (71.2) is formed, which can be isolated and characterized on subsequent acetylation in the form of the furanoside mixture 71.3 (Fig. 2.71). 47 The electrolytic decarboxylation of complex glycosides into the respective C-5-acetoxylated sugars, and subsequent condensation with nitromethane into nitrocyclitols, have been carried out. The products were then hydrogenated and acetylated into protected aminocyclitol glycosides, and the by-products are the aglycons produced on cleavage of the glycosidic bond. Such a multistep synthesis is illustrated by the degradation of sakuraso-saponin (72.1, Fig. 2.72); the aglycons, protoprimulagenin A (72.2) and aegicerin (72.3), can be isolated after the degradation step (1), and the resulting C-5-acetoxy-bis(glycosylated dialdose) can be converted into the nitrocyclitol 72.4, a target for transformation into the amino compounds 72.5.

2.4.3.6. Degradation of Ascorbic Acid Derivatives When investigating the reactions of ascorbic acid (73.1) with diazonium salts a degradation process characteristic of the endiol structure, was observed 48 (Fig. 2.73). First, an arylazo compound (73.2) is formed, which is then converted into the 2-(4-methylphenyl)hydrazide of (3R,4S)mono(tetrahydro-4-hydroxy-2-oxo-3-furanyl) oxalate (73.3). In hot water the hydrazidc 73.3 can be split into L-threonic acid (73.4), easily isolable in form of its derivatives. 48 The epimeric isoascorbic acid (D-arabino-ascorbic

CO~H H

OH

O ( OH

71.7

-e @ OH - ' '3~'" "~"2 "=

I-- HO iH O

I_

O

L_____],

o.

-] O

|

1, CH3OH, H (E) 2, Ac20, pyridine

_t

71.2

HC(Oo~ACH3)~ O

_=

c

OCH3

OAc

71.3 Methyl e~- and ~-D-xylo-pentodialdo(1,4)-furanoside dimethylacetal [O~]D= 0 (CHCI3) (in case of both anomers) 47

F I G U R E 2.71

2.4. DEGRADATION OF SACCHARIDES WITH OXIDATIVE METHODS

CH2OH

.~~o HO

COOH L O

X,o

7

~7~ X---~ r, ?H20H() 6 O~

443

H

r o i'*"

' ....'

L---o/

HO ~H

CH3

0 OH OH 72.1 (sakuraso-saponin)

1) -e- / AcOH 2) CH3NO2 / NaOMe-MeOH

CH2OH

.~

l

l

HO

I ..L-oj

0

~_=

T" " ' - " 0

0

OH OH 72.4 R = NO2 72.5 R = NHAc

72.2 X = oc-OH, I]-H: Protoprimulagenin A 72.3 X = O: Aegicedne

FIGURE 2.72

acid) can be degraded 4s into D-erythronic acid with this method. The following procedure 49 gives reproducible experimental details for the execution of this latter degradation.

444

2 DESCENDING SYNTHESIS OF MONOSACCHARIDES

ohio

H~~H

OH OH

OH

~ OH

p-TolN2Q HSO4Q

O

/O N

H(~ (=N--Tol

oH

73.2

73.1

R10 OR2 H I g H

+

HO2C-CONHNH-p-Tol

\0/~-0

A, H20 FIGURE

r--73.3 R1 = H; R2 = COCONHNH-pTol /L.1~73.4 R1 = R2 = H

2.73

(-)-(3R-cis)-Mono(tetrahydro-4-hydroxy-2-oxo-3-furanyl) ester 2-(4-methylphenyl)hydrazide of ethanedioic acid (73.3) 49 In a 3 liter, three-necked, roundbottomed flask equipped with an air-driven Teflon paddle stirrer, thermometer, and dropping funnel is placed 500 ml of deionized water. With stirring, 53.3 ml (98.44 g, 0.96 mol) of concentrated sulfuric acid is added, when the temperature rises to --40~ Para-toluidine (53.3 g, 0.5 mol) is added with vigorous stirring at this temperature, and within a few minutes a dark-yellow solution is formed. This is cooled in an ice bath when the sulfate precipitates. To the intensely stirred, dense slurry, at 3~ is added dropwise a solution of 35 g (0.507 mol) of sodium nitrite in 63 ml of deionized water over 25 min, while the internal temperature is kept at 3-8~ The resulting diazonium salt solution is stirred at 2-5~ for 30 min, whereupon a solution of 75.5 g (0.429 mol) of D-(-)arabino-ascorbic acid (73.1) in water (500 ml) is added dropwise over a period of 30 min, at --4-5~ with rapid stirring. An orange color forms along with gummy brown material that may impede stirring somewhat. When the addition is complete, the mixture is slowly warmed to room temperature with a water bath and then stirred for 3 h at room temperature, during which time a yellow solid forms. This is filtered with suction and washed with 700 ml of water in small portions. The solid is then washed with 200 ml of ice-cold 96% ethanol in small portions. The filter cake is refluxed with 1 liter of 96% ethanol in a 3-liter round-bottomed flask for 15 min. The slurry is allowed to cool to room temperature and kept at this temperature overnight. The slurry is filtered with suction and the solid is washed with 250 ml of ice-cold 96% ethanol in small portions. After drying at 45~ using water aspirator pressure and then high vacuum, 70 g (55.5%) of the hydrazide lactone is obtained as a white solid, m.p. 182-184~ (dec.), [o~]~ -59.3 (c = 0.5 in ethanol).

(-)-(3R-cis)-Dihydro-3, 4-dihydroxy-2(3H)-furanone

(o-erythronolactone)

In a 2-liter one-necked, round-bottomed flask, equipped with a reflux condenser, magnetic stirring bar, and heating mantle, a slurry of 69.9 g (0.238 mol) (73,4) 49

445

2.4. DEGRADATION OF SACCHARIDESWITH OXIDATIVE METHODS of the preceding hydrazide (73.3) in 700 ml of deionized water is heated to reflux under argon with stirring, and reflux is continued for 50 min. Then, the resulting yellow solution is cooled in an ice bath with stirring to produce a dense precipitate. At --~5~ the solid (oxalic acid tolylhydrazide) is filtered off and washed with small portions of 250 ml of water. The washings-filtrate combination is extracted with 3 • 200 ml of ethyl acetate. The organic phase is discarded, and the aqueous phase is concentrated under diminished pressure at 50~ and the resulting syrup is dried in high vacuum at 40~ The residue (which is crystallizes on seeding) is taken up in 500 ml of ethyl acetate at reflux and filtered hot through a pad of Celite. The filter cake is washed with ---25 ml of ethyl acetate, and the filtrate is allowed to cool to room temperature and refrigerated overnight at --~5~ The crystals are filtered by suction, washed with 75 ml of cold ethyl acetate in small portions, and dried under high vacuum at room temperature to furnish the desired title lactone (20.7 g, 73.7%), as colorless needles, m.p. 97.5-99~ [a]~ -72.07 (c = 0.487 in water).

L - A s c o r b i c acid (74.1) c a n b e directly degraded i n t o L - t h r e o n i c acid (74.4) in a r a d i c a l p r o c e s s b y t r e a t m e n t w i t h h y d r o g e n p e r o x i d e (Fig. 2.74). T h e c h a i n s h o r t e n i n g p r o c e e d s 5~ via d e h y d r o a s c o r b i c a c i d (74.2) a n d a p e r o x i d e (74.3) to r e s u l t in t h e acid 74.4, i s o l a t e d as t h e c a l c i u m o r l i t h i u m salt. T h e s a m e d e s c e n d i n g p r o c e d u r e w i t h t h e 5 , 6 - O - b e n z y l o x y e t h y l i d e n e a c e t a l of L - a s c r o b i c a c i d h a s also b e e n r e p o r t e d . 53

Preparation of calcium L-threonate (Ca salt of 74.4)50 Calcium carbonate (2 g) is added to a solution of L-ascorbic acid (74.1; 1.36 g, 10 mmol) in water

OH OH~ O HO

74.1

OH~o~ OH

H202 #

OH

OH O

HO

Oe

o

~176 o

74.2

t

H202

OH OH

OH

~OH OH

O~C= O ~

HO~C~0 0 ~c ~OH

C02H

I

O

OOH

H20

H O ~ OH + (CO2H)2 OH 74.4 FIGURE 2'74

| //

0

I

OOH 74.3

446

2


(25 ml), and the mixture is cooled in an ice bath and shaken gently during the addition of 30% hydrogen peroxide (4 ml) in small portions. The mixture is kept at 30-40~ for 30 min, and then treated with 0.4 g of activated carbon (Norit), and heated on a steam bath to decompose the excess of hydrogen peroxide. When evolution of oxygen has ceased, the hot mixture is filtered, and the filtrate is concentrated under diminished pressure (bath temperature - 3)-D-arabinose fl-D-Galactopyranosyl-(1 --->3)-o-arabinose

65 60 53 51

It is i n t e r e s t i n g to n o t e t h a t n e i t h e r a - L - a r a b i n o p y r a n o s y l azide, ]~-Dr i b o f u r a n o s y l azide, fl-maltosyl azide, 2-deoxy-fl-D-arabino-hexopyranosyl azide, n o r 2 - O - m e t h y l - / 3 - D - g l u c o p y r a n o s y l azide c o u l d be d e g r a d e d b y an analogous irradiation procedure. 5

2.4.6.2. Metal-Ion-Catalyzed Photochemical Descending Syntheses of Aldoses W h e n an o x y g e n - p u r g e d p y r i d i n e s o l u t i o n of an a l d o s e (89.1) is irradia t e d in t h e p r e s e n c e of f e r r i c ( I I I ) salts, a fragmentation reaction o c c u r s (Fig. 2.89), r e s u l t i n g in t h e f o r m a t e e s t e r (89.2) of t h e o n e - c a r b o n - d e s c e n d e d a l d o s e , a n d t h e p r o c e s s is f o r m a l l y similar to t h a t of t h e l e a d t e t r a a c e t a t e o x i d a t i o n of free, r e d u c i n g s a c c h a r i d e s (see S e c t i o n 2.4.2). A s t h e byp r o d u c t s , t h e t w o - c a r b o n - d e s c e n d e d a l d o s e - 3 - O - f o r m a t e s a r e also prese n t 7-1~ in t h e r e a c t i o n m i x t u r e s .

__oOo

HO " ~ "

"

HO

Z'.'.'.'.~(

U ,,i#e

#

1 L

O

O"CH

Ho

ol

--CHO l

_I

89.1

OH 89.2

FIGURE 2.89

OH

467

2.4. DEGRADATION OF SACCHARIDES WITH OXIDATIVE METHODS

OH O~ H

HC(OCH3) 2

o

,,~

OH

1, hv, TiCI 4, CH3OH

OH

2, Ac20, pyridine

O c

~

J OH

OCH3

I OAc

90.1

90.2

FIGURE 2.90

Degradation o f D-mannose to 1,2,3-tri-O-acetyl-D-arabinopyranose 1~ In a Pyrex vessel a mixture of D-mannose (9 g, 50 mmol), pyridine (900 ml), and ferric(Ill)trifluoromethanesulfonate (0.25 g, 0.5 mmol) is irradiated with a water-currentcooled high-pressure mercury lamp (2 kW, type Sen SL-2000) for 8 h, by passing oxygen through the reaction mixture. Then acetic anhydride (70 ml) is added, and the mixture is stirred for 14 h. Following evaporation (bath temperature -

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